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English Pages 259 Year 2002
Biology in Physics Is Life Matter?
Biology in Physics Is Life Matter?
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Series in Polymers, Interfaces, and Biomaterials Series Editor Toyoichi Tanaka Department of Physics Massachusetts Institute of Technology Cambridge, MA, USA Editorial Board: Sam Safran Weitzman Institute of Science Department of Materials and Interfaces Rehovot, Israel
Alexander Grosberg Department of Physics Massachusetts Institute of Technology Cambridge, MA, USA
Masao Doi Applied Physics Department Faculty of Engineering Nagoya University Nagoya, Japan
Other books in the series: Alexander Grosberg, Theoretical and Mathematical Models in Polymer Research: Modern Methods in Polymer Research and Technology (1998). Kaoru Tsujii, Chemistry and Physics of Surfactants. Principles, Phenomena, and Applications (1998). Teruo Okano, Editor, Biorelated Polymers and Gels: Controlled Release and Applications in Biomedical Engineering(1998). Also Available: Alexander Grosberg and Alexei R. Khokhlov, Giant Molecules: Here, There, and Everywhere (1997). Jacob Israelachvili, Intermoleculer and Surface Forces, Second Edition (1992).
Biology in Physics Is Life Matter?
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Konstantin Bogdanov
Institute of Developmental Biology Russian Academy of Sciences Moscow, Russia
ACADEMIC PRESS A Harcourt Science and Technology Company
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This book is printed on acid-free paper. ( ~ Copyright 9
2000 by Academic Press
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ACADEMIC PRESS A Harcourt Science and Technology Company 525 B Street, Suite 1900, San Diego, CA 92101-4495, USA http://www.apnet.com Academic Press 24-28 Oval Road, London NW1 7DX, UK htt p ://www. h buk.co, uk/a p/
Library of Congress Catalog Card Number: 99-65060 International Standard Book Number: 0-12-109840-0 Printed in the United States of America 9900010203EB98765432 1
To my parents
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Contents
Foreword xi Acknowledgments Introduction xvii
O
O
XV
Electricity Inside Us
1
Luigi Galvani and Alessandro Volta 2 Cell Membrane: Lipid Bilayer and Ionic Channels 4 Resting Potential 7 Action Potential 11 Nerve Impulse Propagation 14 Nodes of Ranvier 18 A Menu for a Person Condemned to Death Living Electricity Around Us 21 Electrical Compass 25 Electricity in Plants 29
H e a r t Pulse
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33
Arteries, Blood, and Erythrocytes 34 Velocity of Pulse Wave 40 Reflection of Pulse Waves 42 Equilibrium of the Blood Vessel Wall: Aneurysm 45 Murray's Law 48 Blood Circulation in Giraffe and Space Medicine 50
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CONTENTS How Blood Pressure and Blood Flow are Measured 53 Blood Color and the Law of the Conservation of Energy 61
O
Crocodile Tears and Other Liquids
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Water in Us 65 Amazing Filter 68 Cryobiology and Biological Antifreezes
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Inhale Deeper
O
Hunt for Cells in an Electric Field
O
How Nature Listens
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Breathing and Soap Bubbles 83 It's Not So Simple 85 Exceptions to the Rule 88 Countercurrent: Cheap and Effective 90 Diving 91 High Frequency Ventilation and Einstein's Formula 98 The Physics of Cough 104
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Principles of Dielectrophoresis 110 113 Cell ID in an Alternating Electric Field Cell Separation Using Traveling-Wave Dielectrophoresis 116 119 Electroporation of Cell Membranes
121
Let's Recall the Basics of Acoustics The Ear in Brief 124 The Middle Ear 126
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CONTENTS
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Cochlear Amplifier 129 Otoacoustic Emissions, or Ear Sounds What Is a Cochlear Implant? 137 Sound Localization 139 Echolocation 143
0
Bone
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Composite Structure of Bone 154 Compact versus Spongy Bone 155 Bone Strength 157 Osteoporosis 160 Wolff's Law and Bone Remodeling 161 Karate Mechanics in Short 163 Leg Tendons~Living Springs 165
Optics of the Eye
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Photoreceptors and Visual Pigments Tapetum~Living Mirror 175 Infrared Vision 178 Compound Eyes 181 How Ommatidia Help One Another Microvilli See Polarized Light 191 Animal Maps 195
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Magnetic Sense
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On a Wing and a Vector 200 Magnetites Inside Us 203 Basics of Magnetic Orientation 206 Paleomagnetism and Magnetotactic Bacteria 209
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CONTENTS
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Optima for Animals: from Mouse to Elephant 211 Body Mass and Lifestyle 211 AIIometry of a Skeleton 212 Stepping Frequency and Gaits 214 Jumping Performance and Body Mass Shark and Mackerel 217 Carrying Loads on the Head 218 Breathing-Tuned Oscillator 219 Energy and Body Mass 221 Living Wheel? 225 References 227 Index 235
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Foreword
"The whole of science is nothing more than a refinement of everyday thinking," A. Einstein. However, along with the development of human society, both the weight and the role of different sciences have varied. In the seventeenth and eighteenth centuries mechanics was focused upon, including heavenly mechanics, but in the nineteenth century it is already difficult to establish whether it was physics (and mechanics) that played the leading part, or whether it was chemistry or biology. But from the end of the nineteenth century and until the middle of the twentieth century, physics domineered; it was the top priority for all scientists. In 1897 the electron was discovered; soon after; radioactivity and x-rays; in 1900 the quantum theory appeared, and the whole physical outlook of the world changed. The development of physics reached its climax point, first with the special and general relativity theories (1905 and 1915), and then with quantum mechanics (in the 1920s). It was then that the atom and atom nuclei structure were clarified, and as a result, modern natural sciences, including chemistry and biology, started their independent development. Unfortunately, nothing but physics was the crucial factor for both the Abomb and the H-bomb creation. The era of physics was over in the 1950s ~ exactly at that period of time biology suddenly rushed forward, when DNA structure and the nature of genetic code were described (1953). Thus, the development of molecular biology was triggered. Now that we are entering the twenty-first century, it is undoubtedly biology that plays the leading role, as far as the interest of the human society and the development of its potential are concerned. Illustrating this idea very well is one of the most famous international scientific journals, Nature: its basic weekly issue covers all sciences, biology among them. As for its six
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monthly satellites, all of them contain articles only on biology or areas related to biology: Nature: Genetics, Nature: Structural Biology, Nature: Medicine, Nature: Biotechnology, Nature: Neuroscience, Nature: Cell Biology. Of course, the current progress in biology would be impossible without modern physical devices and methods. In this respect, particularly in technology and computer science, physics has not shifted to the background. On the other hand, biology provides new food to physics, particularly when it offers examples of information control and transfer. Examples of this kind show how biology is valid for physicists, and how physics is important for biologists. This book by Konstantin Bogdanov spans the two sciences, and should be equally interesting for both physicists and biologists. In conclusion, I would like to touch upon a problem of primary importance, that of reduction: Is it possible to explain biology through physics? Since we know the laws of the electron and atom nuclei interaction that form the matter of living organisms, we should be able to explain all the living organisms' processes from the point of view of physics. A lot has been achieved by scientists working in this direction, and yet there is one thing that remains unclear: the origin of life, the step between life and nonlife. Perhaps the molecular approach will help to clarify the transformation from complex molecules to simplest organisms that can self-regenerate. But can physics explain the emergence of conscience? I personally don't understand it at all. Those who believe in God solve this problem very easily: nonliving matter becomes live when God "inhales" life into it; and it is also God who supplies a human being with a conscience. Unfortunately, this explanation does not convince atheists, me among them; it only substitutes one unknown for another, and is definitely beyond the scientific approach and scientific outlook. Nevertheless, if we remain within this approach, we cannot consider the reduction of biology to modern physics fully proven. What if there are other fields and particles that have not been yet discovered by physicists as well as processes valid for living organisms only, and not for nonliving ones? Of course, this assumption does not reject reductionism in principle, only the reductionism based on what modern physics knows at present. To be honest, I am saying it only to be careful. Most likely, at the fundamental level (fields and particles) no new discoveries in physics are necessary to explain what happens in biology. On the other hand, the physics of complex systems, to say nothing of living organisms, is still quite
FOREWORD
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vague. To solve the problem of reductionism, that is, what connects basic biology with physics, is, to my mind, the central problem of twenty-first century science. Of course, Konstantin Bogdanov's book is rather far from problems of this kind; yet it is indirectly connected with them and can facilitate the interaction of physicists and biologists, which will enable more rapid progress in biology. The objective of the book is to make biology more attractive to physicists. Still it cannot be called popular, as the reader has to have a certain academic background in physics. Every chapter triggers further research and contains comprehensive reference to recent publications. This is not a textbook; rather, it is a collection of separate stories about how physics can be used when biology is studied. The author does not try to categorize the results of biophysical research. This is why what you feel after you have read this book is similar to what you feel in an art gallery. It is quite likely that this method of research in biology can become more attractive, particularly for the physicists who find it difficult to approach complicated physiological processes. This book is very useful for university students and physicists as well as for anyone who is still fascinated by the perplexing script according to which biological processes are carried out in both ourselves and nature around us. Vitaliy L. Ginzburg Member of Russian Academy of Sciences Lebedev's Physical Institute Moscow, Russia
November, 1998
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Acknowledgments
Production of this book would not have been possible without the help of many people. However, the first and most honorable position in this list of acknowledgments must be given to my first teacher in biophysics, Dr. Vladimir Golovchinsky, who introduced me to biophysics three decades ago when I was still an undergraduate at the University of Physics and Technics at Moscow. Special thanks to Dr. Yuliy Brook who gave me the idea to write the book many years ago, and Dr. Alexander Grosberg, who helped me choose the most appropriate style of presentation. I am particularly grateful to Dr. Alexei Chernoutsan who found and recovered the manuscript of my book considered as lost forever. It has been a pleasure working with Mrs. Maria Ovchinnikova, whose skillful work as an artist created a handsome volume from an author's dream. I gratefully acknowledge the various authors and publishers who gave their permission to reproduce several figures and tables. Many thanks to Dr. Zvi Ruder for help and support in preparation of the manuscript for publishing. Finally, I am sincerely grateful to academician Vitaliy Ginzburg for writing the foreword for my book. I promised my wife, Nadejda Kosheleva, that I would not give her the stereotypical public thanks for her support, and I am not doing so! Also, I feel sorry that in the very beginning I forgot to thank Dr. Edward G. Lakatta who taught me to run wishbone, helping me to stay healthy and wealthy while writing this book.
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Introduction
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Life is much too important a thing ever to talk seriously about it. Oscar Wilde, Vera, or The Nihilists, 1883
We are entering the third millenium. Of course this statement is relative: we merely have to deal with decimal notation. If we were using a hexadecimal system to count how many years have passed since Jesus Christ was born, we would have another 2096 years to wait for the third millenium. However, is it the only convention produced by the human mind? The answer is no. "Living" and "nonliving" nature is another example. Can we really distinguish between living and lifeless objects? Since conventions generate one another, for many years different people studied living and nonliving nature separately. Physicists, biologists, and chemists were looking for laws common for nonliving objects, and managed to accomplish a great deal. Meanwhile, biologists were producing piles of data concerning "live" nature that can hardly be systematized. Biological laws are so numerous and complicated that physicists used to feel scared: What would happen to them if the law governing the motion of a stone thrown at a certain angle to the horizon depended on the shape and size of the stone? Or, can you imagine different laws for the motion of bodies thrown up and down? Yet, unfortunately, that is what is going on in biology. For example, however thoroughly we may have studied the law of the rat's heart systole, we find it next to impossible (or impossible) to apply it to a human heart. Likewise, it is necessary to use different equations to describe the process of contraction and relaxation of a muscle, whereas for a steel spring one is enough. Probably that is why the number of publications in biology is a dozen times greater than that in physics as you can see by
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looking through Science, Nature, or Proceedings of the National Academy
of Sciences.
However not all the physicists have been scared off by the complexities of biology. Some, who call themselves "biophysicists," decided to help biologists and crossed the border between the alive and the lifeless. As they stepped over to the other side, the first thing they saw was that biologists speak a language they don't understand. The most interesting thing was that this language was familiar to physicists~ a kind of broken E n g l i s h ~ b u t there were plenty of absolutely unintelligible terms (see the index at the end of the book). Like all aliens, biophysicists have rather mixed feelings as they invade the unknown country of biology. Though scientific curiosity incites them, they realize that it is impossible to learn much without good command of the language. For a long time I had been among such aliens, until I compiled a phrasebook intended to help me communicate with biologists in their language. It is this phrase-guidebook that is offered here. The book is divided into a number of chapters concerning different, rather unrelated, fields of biology. In each chapter you can find the description of some physical law applied to the explanation of specific biological phenomena, which is done to remind you of the native language of physics that you spoke before crossing the boundary. Every tourist usually tries to decide where to go. A big city or wilderness? Of course, in a city you find good service and a lot of sophisticated entertainment, but the impressions to share with friends will hardly come as a surprise to listeners. Besides, it is unlikely that urban tourists could make any real discoveries. Now, unexplored paths is an entirely different m a t t e r - - t h e y make you a pioneer. But how can you get there? And is it really worth the effort? It may very well turn out that you find nothing interesting as you reach the place. Anticipating such questions, Table 0.1 lists large biological "cities" frequently visited by physicists who work in Mechanical and Electrical Engineering departments. The table was created as a result of the analysis of scientific articles found in the database MEDLINE (U.S. National Library of Medicine), published in 1997. Only the articles where the first author worked in Mechanical or Electrical Engineering departments are included. This table provides the answer to another question: In what area of biology can a physicist apply his or her knowledge and still remain a research team leader?
INTRODUCTION
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Table 0.1 Biological issues considered in papers performed in Electrical and Mechanical Engineering departments and published in 1997. Departments of Electrical Engineering, 1997 Issues considered Number of papers published Tomography, Magnetic Resonance ImagingmMethods-analysis Electric stimulationmmethods Ultrasonography~methods-analysis Cardiography--methods-analysis Neural Networks Computer-diagnosis Neurology~methods-analysis Physiology of heart and circulation~models Others Department of Mechanical Mechanics of Bones, Joints, Limbs and Human Body, Prothesis Mechanics of Blood Circulation Cryosurgery & Cryopreservation Minimally Invasive Surgical Procedures, Robotics Others
% of total
36
20
28 19 19 17 17 13
15 10 10 9 9 7
35 Engineering, 1997 79
20 48
40 12 8
24 7 5
25
15
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If you really are fond of travelling and don't like conventions, welcome to a mysterious country m Biology.
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Electricity Inside Us
It is hard to imagine what would happen if we were suddenly deprived of electricity. A global catastrophe, which could destroy thousands, or even millions, of human lives, could very well inspire Stephen Spielberg to make another movie called "Lights off, please." Certainly the people who would suffer the least are those beyond civilization, like the Amish, who live in southeast Pennsylvania and who reject electricity for ideological reasons. Of course, it is possible to de-energize the houses, to live without television, radio, telephone, and PC (as the Amish do), but all the same we cannot be completely "saved" from electricity since electricity is inside us. For more than four centuries scientists have been attempting to define the role of electromagnetic phenomena in the life of humans and animals. But only after Hans Christian Oersted discovered that the electric current flowing through a wire loop can deflect a magnetized needle, did it become possible to create sufficiently sensitive galvanometers. With the help of these galvanometers, Carlo Matteuchi (1838), and later Emil du Bois-Reymond (1848), measured the electrical fields generated by the contraction of the muscles of animals and humans. However, living organisms are not only generators of electricity, but have high sensitivity to an electromagnetic field, whereby it is in no way possible to explain the observed effects by the thermal action of such a field. It is well known, for example, that the general anesthesia (the loss of
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Chapter 1. Electricity Inside Us consciousness and of the sensitivity to pain) can be obtained by passing the impulses of alternating current through a human brain, which is frequently used for anesthesia during surgical procedures. The direction of the lines of force of the electric field of the earth serves as a compass for long-distance migrations of the Atlantic eel. The navigation abilities of pigeons are based on the perception of the magnetic field of the earth. Skeletal bones inside an electric field grow in a different way, which theoretically can be used for treatment of fractures. The list of the biological effects of an electromagnetic field can be continued, but it is not our task.
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Luigi Galvani and Alessandro Volta Luigi Galvani, Professor of Anatomy from Bologna University, was the first to discover the effects of an electric field on a living organism. Since 1775 he was interested in the connection between electricity and life. In 1786 one of the professor's assistants, while separating a muscle from a frog's leg with a scalpel, happened to touch the nerve going to this muscle. At this very moment a static electricity generator was rotating on the same desk. Each time the electric machine produced a discharge, the frog's muscle contracted. Galvani concluded that the electricity would somehow go into a nerve, which would result in a muscle contraction. He devoted the following five years to the study of how different metals can cause muscle contractions. Galvani came to the conclusion that, if a nerve and a muscle lay on identical metallic plates, the shorting of plates by a wire did not give any effect. However, if the plates were made of different metals, their shorting was accompanied by a muscle contraction. Galvani reported his discovery in 1791. He thought that the reason why a frog's leg jerked was the "animal electricity" generated inside an animal's body, whereas the wire only provided for the closing of an electric circuit. He sent a copy of his work to Alessandro Volta, the physics professor from Pavia (northern Italy). Alessandro Volta repeated the experiments of Galvani, and obtained the same results. At first he agreed with Galvani's conclusions but then he paid attention to the fact that the animal electricity emerged only when there were two different metals in a circuit. Volta showed that when two different connected metals are placed on a human tongue, it feels like tasting
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something. Likewise, if you quickly touch your eyeball by a tin plate while having a silver spoon in your mouth, the shorting of the spoon and plate will give light sensation. Trying to refute Galvani's thesis about the existence of animal electricity, Volta suggested that a circuit that consisted of two different metals, both in contact with a salt solution, could be a source of direct current, unlike an electrostatic machine, which could only produce electric discharges. This proved to be true. In 1793 Volta published his paper containing the description of the first source of direct current (later called galvanic). Although soon after, Galvani showed that animal electricity exists in the electric circuits without bimetallic contacts as well, he could not continue his dispute with Volta. In 1796 Bologna became a French territory, and Galvani, who refused to recognize a new government, lost his position in the university. He had to look for refuge at his brother's place, but he did not practice science again, and died in 1798. In 1800 Volta presented his discovery to Napoleon and received a great reward for it. Thus, the dispute of two compatriots who had different spirit, education, and political views, triggered the development of modern physics and biology. Who was right in this dispute? Does animal electricity exist or not? In his latest experiments Galvani used two muscles at a time arranging them in such a way that the nerve leading from one muscle was placed on the other muscle (Figure 1.1). It turned out that at each muscle-1 contraction caused by the current passing through its nerve, muscle 2 also contracted, as if current passed through its nerves as well. From these experiments Galvani concluded that a muscle at the moment of contraction served as a source of electric current. So it was demonstrated (though, in an indirect way) that the animal electricity exists. But it was not until half a century later, in 1843, that the German physiologist Emil du Bois-Reymond demonstrated the presence of the electric fields in nerves and muscles, using the latest available electromeasuring instruments. It is interesting that he was assisted by Werner Siemens and Georg Halske, who were hardly known at the time. Later, in 1847, they founded the telegraph company Siemens and Halske, which soon developed into a famous industrial empire. So what is the source of the animal electricity? It took another half a century to answer this question.
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F I G U R E 1.1. electricity.
The set-up of L. Galvani's experiment to prove animal
Cell Membrane" Lipid Bilayer and Ionic Channels
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We consist of cells as a house consists of bricks. The analogy cannot be further developed because we consist of hundreds or even thousands of types of "bricks". The cells of skeletal muscles differ from nerve cells, and red blood cells seem to have nothing to do with cells of blood vessels. Nevertheless, there is a property which makes all the cells alike: all of them are enclosed by a membrane. The main feature of a living organism is to be "picky" in its relations with the environment. What helps here is the selective permeability of the membranes of the cells. The cell membrane is its skin, which is about 5 nm wide. The cell membrane selectively reduces the speed of molecules moving into a cell and out of it. It defines which molecules are to penetrate a cell, and which are to remain beyond its limits. Thus, the function of a cell membrane is in many respects similar to that of security for a foreign embassy building. A high fence around the building and several entrances where security people decide who can be let inside and who can't usually serve this purpose. The role of a "high fence" in a cell membrane is played by the phospholipid bilayer (Figure 1.2), which forms its basis and makes it impervious for most water-soluble molecules. Phospholipid is a very long
Cell Membrane: Lipid Bilayer and Ionic Channels
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molecule, which has a polar head group and two hydrophobic hydrocarbon tails whose length varies from 14 to 24 carbon atoms. Phospholipid molecules stick to each other in water by hydrophobic tails forming a bilayer, so that their hydrophylic polar heads, shown as beads in Figure 1.2, remain in contact with water molecules. Different ions moving along the gradient of concentrations can cross a cell membrane only where it has pores or channels specifically intended for crossing over. The ionic channels (shaded in Figure 1.2) are big protein molecules that create, in the lipid bilayer, pores for water and for the vitally important ions sodium, potassium, calcium, and chlorine. Some parts of these protein molecules are charged, therefore they can move due to the changes in the electric field, thus altering the configuration of the entire ionic channel. As a result, the channel conductivity changes. In Figure 1.2 these charged parts of the ionic channel are schematically shown as gates that open (activation) and close (inactivation) the gap of the ionic channel. There are a lot of ionic channels that differ from one another by their features. As a rule, each ionic channel is adapted to let only one of the previously listed ions through the membrane. Such channels are called selective potassium, sodium, etc., depending on which ions they allow to pass. However, there are also channels that let several types of ions through, called nonselective. The density of ionic channels is uneven, ranging from several units to several thousand units per 1 0 - 6 mm 2 of a membrane. Though the molecular structures of many channels' proteins are already well-known, the mechanisms of selective permeability of these channels with respect to different ions are still not clear. The most reasonable explanation of the ionic channel selectivity seems to be the different size of ions. But then how can a selective channel for a large ion be created? Evidently, smaller ions will also pass through a selective channel for a larger ion. Anyway, what does a size of an ion mean? Water is a strong polar solvent. Therefore, each ion in the aqueous solution is enclosed within a shell of several water molecules (hydration shell). How does the channel's protein recognize the type of ion if the latter is surrounded by a water shell? The answer is simple: Before entering the channel the ion partially undresses, and proceeds through the channel halfdressed. Therefore, the cross section of such a half-dressed ion may have very weird shapes. The protein channel, in its narrowest place (called the selective filter), is considered to have the cross section transmitting its own
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FIGURE 1 . 2 . Biological membrane. Top: The general view ofaphospholipid bilayer with ionic channels floating in it. Bottom: Schematic section through the ionic channels in different states, closed (activation gate is closed), open, and closed (inactivation gate is closed).
ions only. Thus, for example, according to the hypotheses of Dwyer et al. (1980), the selective filter of the potassium channel must have a circular cross section of 0.33 nm in diameter, and the selective sodium filter, a
rectangular cross section of 0.31 x 0.51 nm. Some ions can move inside a cell even when their concentration outside it is less than inside. It happens because of the presence in the lipid bilayer not only of the channel proteins, but also of the proteins that act as ion pumps.
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Table 1.1 Concentration of some ions inside and outside of cardiac myocytes.* Ion type
Na §
Concentration, mM/I inside 10
140
K+
150
CICa 2 +
20 < 0.001
Organic anions
~120
outside
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145 2 m
*The data are taken from comparing the ionic composition of intracellular and extracellular solutions in the experiments with the voltage clamp.
The activity of the membranous protein-pumps is accompanied by great energy consumption, and as a result ion concentration inside a cell can be dozens, or even thousands, of times higher (or lower) than that outside (see Table 1.1). For example, potassium ion concentration inside a cell is 30 times higher than in extracellular liquid. On the contrary, the sodium ion concentration inside a cell is 14 times lower than outside. As we can see, the differences in potassium and sodium ion concentrations on each side of a membrane are necessary for electric fields to exist in living organisms. It turned out that at rest, a cell membrane is permeable only for the potassium ions. In other words, when muscle cells are not contracting and the nerves are resting rather than thinking, only potassium channels are opened in their membranes. On the other hand, when the same cells are active, or, to put it in other words, excited, their sodium and calcium channels are opened as well, increasing for a short time the concentration of respective ions inside a cell. So what is it that controls the channel activity?
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Resting Potential Let's try to imagine what might be the result of the difference in the potassium ion concentration on each side of a cell membrane with high permeability for these ions. (It was this problem that was posed and solved in 1902 by German physiologist Julius Bernstein, the author of membrane excitation theory.) Suppose that we immerse a cell with a membrane that is
Chapter 1. Electricity Inside Us permeable only for the potassium ions into electrolyte, where their concentration is lower than inside the cell. Immediately after the membrane comes into contact with the solution the potassium ions begin to get out of cells, like gas gets out of an inflated balloon. However, each ion carries a positive electric charge, and the more potassium ions leave a cell, the more electrically negative its contents becomes. Therefore, each potassium ion coming out of cells will be affected by an electric force preventing it from leaving the cell. Eventually, the balance will be established, whereby the electric force acting on a potassium ion in the membrane channel will be equal to the force resulting from the difference of potassium ion concentrations inside and outside the cell. It is obvious that such balance between internal and external solutions will set up a potential difference. If the potential of the external solution is taken to be a zero potential, the potential inside a cell will be negative. This potential difference, the simplest of the observed bioelectrical phenomena, is called the r e s t p o t e n t i a l of a cell. As it was shown by W. Nernst in 1888, in an ideal case when a cell membrane is permeable only for the ions of a single type (S), a potential difference E s is established on a membrane. This potential difference is called equilibrium potential for the given ion:
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E s = E, - E 2 = (Rr/zeA)ln([S]2/[S]!
)
(1.1)
where e is the electron charge, z is the valency of ion S, A is the Avogadro constant, R is the gas constant, T is the temperature in K, [S]~ and [S]2 are the concentrations of the ion S on each side of a membrane. Substituting [K+]2/[K+]1 = 1/30 and T = 300 in Eq. (1.1), we obtain E K = - 8 6 m V , which is close to experimentally obtained values of a resting potential of many living cells. It is worth mentioning that voltage drop on a cell membrane, which is less than 0.1 V, happens on a segment about 10 -6 cm long. Therefore, the strength of the electric field inside a membrane can reach huge values m about 10 s V/cm, which is close to the strength of the electrical breakdown of this membrane. Thus, as a result of the ion channels existence and the great difference in concentration between intracellullar and extracellular solutions for many ions (see Table 1.1), potential difference on cell membranes appear. If
Resting Potential
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channels for one ion only are opened in a membrane, the potential difference on it will be equal to the equilibrium potential for this ion. But what will happen if the membrane is permeable for several types of ions at once? Goldman (1943) and Hodgkin & Katz (1949) deduced the formula for a potential difference, E, on a membrane permeable for several ions at once assuming that the electrical field inside a membrane is uniform:
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R T lnPNa [NaJ~ + PI< LKJe E - ze---A PNa LNaJ/+ PI< LKJi
(1.2)
where [K] and [Na] are the concentration of potassium and sodium ions, respectively, inside a cell (with the index i) and outside a cell (with the index e); PK and PNa are the permeabilities of a membrane for these ions; and the remaining symbols are the same as in Eq. (1.1). It is worth mentioning that the membrane permeability for a specific ion is expressed as the ratio of a diffusion coefficient of this ion in a membrane to its width. It follows from Eq. (1.2), known as the c o n s t a n t field f o r m u l a , that when there are several types of ionic channels a membrane potential depends on the relative permeability of these channels. In other words, the higher the membrane permeability to any ion, the closer the membrane potential to the equilibrium potential for this ion; the potential is calculated using Eq. (1.1). It is not that simple to measure the difference of electric potentials for living cells: the cells are very small. Because regular probes attached to every voltmeter can't be used here, glass pipettes (microelectrodes) are used, with a tip diameter less than one micrometer. The pipette is filled with a strong electrolyte solution (for example, three-molar solution of potassium chloride). The contents of the pipette are then connected through a metallic conductor with the input of a voltmeter with a high (more than 109 Ohm) resistance since the pipette resistance sometimes approaches 108 Ohm. The skill of a microsurgeon as well as special micromanipulators are necessary here to insert a microelectrode into a cell, still keeping it alive (Figure 1.3). The problem is that as soon as the opening in a membrane appears, the ion concentration inside a cell will be approaching its values for the extracellular medium; that is, sodium and calcium ions will be entering the cell, and potassium ions will be leaving it. This will cause the inevitable death of the cell. But even if we were lucky enough to insert a microelectrode inside a cell without killing it, while measuring the potential difference on each side of a
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F I G U R E 1 . 3 . Measurement of the potential difference across the membrane of a living cell.
membrane we won't be able to keep track of the ions motion in a separate channel. Instead, we will see the result of the activity of millions of different ionic channels. To follow the ions movement through single channels not only is the skill of a microsurgeon necessary, but also electronic instruments with extremely low levels of interior noise, as the value of electric current through a single channel often does not exceed 1 pA. Figure 1.4 shows the technique (patchclamp recording) I that makes it possible to register the conductivity of a single channel and to record the changes of this conductivity in time. The first thing that attracts the attention is that at a constant voltage applied to a channel, the current passing through it changes in steps. Starting at a zero, when the channel is closed, it reaches its m a x i m u m value in the open state. Thus, the channel activity is of random nature, and we can only estimate the probability of its opened and closed states.
l In 1991 the German scholars Erwin Neher and Bert Sakmann were awarded the Nobel Prize for the development of this technique and for the analysis of the functioning of single ionic channels.
11
A c t i o n Potential
,pAI
I
I
10 ms F I G U R E 1 . 4 . The patch-clamp technique used to record the conductances of a single ionic channel. Top: cross-sectional view of a glass pipette filled with electrolyte; its opening is closed with a piece of cellular membrane that contains just one channel. Bottom: record of the current through an ionic channel; closed corresponds to zero current through the channel.
Action Potential
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What precedes the contraction of a muscle cell? W h a t happens in nerve cells
when we react to a prick of a needle? W h a t is the excitation of cells? What is
zy zyxwv Chapter 1. Electricity Inside Us
12
surprising is that in all these cases the same process takes place I a shortterm change of the potential difference on a membrane. As we already know, in the state of rest the intracellular medium is charged negatively with respect to the extracellular one. During the excitation, the electronegativity of the intracellular medium decreases for a very short time (from I msec up to several decimals of a second), and sometimes a cell even becomes positively charged with respect to the extracellular solution. This transient ch~.nge of the potential difference is called action potential, and if it happens in nerve cells, it is called nerve impulse (Figure 1.5). In 1963 A. L. Hodgkin and A. F. Huxley were awarded the Nobel Prize for the discovery of the nature of the action potential. What followed from their experiments performed on a giant axon of Loligo squid was as follows. 1. The initiation of the action potential results from a short-term increase of the membrane permeability for sodium ions. 2. The ionic permeability of the membrane is a function of two variables: membrane potential and time; therefore, if the potential on a membrane is fixed (voltage-clamp technique), the task can be reduced to the study of permeability dependence on time only.
mV +501 (D 0 C (D .D 13 E .m
1
C (D
II
I
5
10
time, ms
0 O. (D C
4__ action potential
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E E
or nerve impulse -50
resting potential
FIGURE 1.5. impulse.
Change in the voltage across a membrane during a nerve
13
Action Potential
It turned out that the sodium channel of a nervous cell membrane differs from the potassium one. Its average conductivity (the probability of the open state) grows very quickly with the increase of the potential U of the intracellular medium which is counted from the potential of the external solution, taken as zero (Figure 1.6). Now let's suppose we are able to increase U by 20-30 mV (e.g., by passing the current through a cell). As soon as it happens, the sodium channel conductivity increases and, according to Eq. (1.2) U will increase even more, hence a sodium channel conductivity will increase too, and so on. Evidently, a small initial increase of U should trigger a fast explosion-like process, as a result of which the membrane permeability for the sodium ions increases to its maximum possible values and becomes dozens of times higher than its permeability for the potassium ions. The reason why it happens is that there are about 10 times as many sodium channels in a membrane as potassium ones. Therefore, if we disregard the membrane permeability for potassium, it is possible to evaluate potential U at the end of this fast process by using Eq. (1.1) and assuming [Na+]2/[Na+]l- 14. After the substitution we obtain the potential leap during this transient process (equal to about 0.15 V). However, the sodium channel has another feature peculiar to it, but not for the potassium one. Its conductivity depends not only on the voltage on
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0
-50
0
+50
membrane potential, mV FIG U R E 1 . 6 . Dependence of the probability of the open state of the sodium channel on the voltage across a membrane.
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14
Chapter 1. Electricity Inside Us
the membrane, but also on how much time has passed since its opening. The sodium channel can be open only for 0 . 1 - 1 0 m s depending on the temperature and the kind of cell (Figure 1.7), which results in the return, after the sharp increase 0.15 V, of the potential difference on a membrane to its initial value, the resting potential. U returns to the resting potential even faster because the higher the conductivity of the potassium channels, the lower the sodium channel conductivity. The obtained results allowed A. L. Hodgkin and A. F. Huxley to propose a mathematical model that simulates the action potential.
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Nerve Impulse Propagation
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How do our senses inform the brain of what is going on around us? How do the different parts of our organism exchange information? For this purpose, nature devised two special communication systems. The first system, humor (from the Latin humor, meaning moisture, liquid), is based on diffusion or the transposition of biologically active substances with a liquid flow from where they are synthesized to the entire organism. This system is the only one that functions in protozoa as well as in plants.
.
r
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0
, 1
time, ms
FIG U R E 1 . 7 . Inactivation of the sodium channel that occurs due to the closing of the inactivation gate (see Figure 1.2). Axis of ordinates: relative decrease of the sodium channel conductance upon attaining its maximum value; axis of abscissas: time.
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Nerve Impulse Propagation
15
Metazoans (including you and me) also have a nervous (from the Latin nerves, meaning sinew) system composed of a great number of nerve cells with appendices, the nerve fibers, running through the whole organism (Figure 1.8). The membrane of a nerve cell body is excited as soon as nerve impulses come to it from the adjacent cells through their appendices. This excitation passes over to a nerve fiber of this cell, and moves through it to adjacent cells, muscles, or organs at a speed of up to a hundred meters per second. Thus, an elementary signal transmitting the information from one part of an animal's body to another is a nerve impulse. Unlike the dots and dashes in Morse code, the duration of a nervous impulse is constant (about 1ms), and the transmitted information can be encoded in a most peculiar way in the sequence of these impulses. Quite a few of the well-known scientists of the past have attempted to explain the mechanism of excitation propagation along a nerve. In his famous book Optics, published in 1704, Isaac Newton suggested that the nerve had the properties of optical light guide. Therefore, "the ether vibrations" generated in a brain at will could propagate from there along solid, transparent, and homogeneous nerve capillaries to muscles, making them contract or relax. The founder of Russian science, the first Russian academician M. V. Lomonosov thought that the propagation of excitation along a nerve happened due to the movement of a special "rather fine nerve liquid" inside it. It is interesting that the velocity of propagation of excitation along a nerve was measured for the first time by a famous German physicist, mathematician, and physiologist Hermann Helmholtz in 1850, a year after A. Fizeau had measured the speed of light. What makes it possible for the nerve impulse to propagate? What features of a nerve fiber define the velocity of propagation of an impulse through it? To answer these questions, let us consider the electric properties of a nerve fiber. It is a cylinder whose lateral surface is formed by a membrane separating the inner electrolyte solution from the outer. This gives the property of a coaxial cable to a fiber, with the cellular membrane acting as insulation. But the nerve fiber is a very poor cable. The insulation resistance of this living cable is approximately 10 s times less than that of a usual cable, as the thickness of the former is 1 0 - 6 cm, and the thickness of the latter is about 1 0 - 1 c m . Besides, the inner conductor of the living cable is an electrolyte solution whose resistivity is a million times higher than that of
16
Chapter 1. Electricity Inside Us
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F I G U R E 1 . 8 . A considerably simplified diagram of connections between nerve cells, organs of senses, and muscles.
metal. That is why unexcited nerve fiber does not transmit electric signals
over great distances too well. It is possible to show that the voltage on a m e m b r a n e of such fiber will exponentially decrease with a distance from the voltage source (Figure 1.9). The value 2 used in an exponent, and which determines the decay rate of an electric signal in a nerve fiber, is known as the space constant of a fiber. The value of a space constant depends on a fiber diameter d, a unit area resistance
of its membrane, r m and the resistivity r i of a liquid inside a fiber. This dependence has the following form: ]t.2 = ( d r m ) / 4 r
i
(1.3)
Nerve Impulse P r o p a g a t i o n
zyxwvu 17
Eq. (1.3) does not include the resistivity of the medium around the fiber as the dimensions of the external conductive liquid are mostly a lot larger than the fiber diameter, and it is possible to consider the outer solution equipotential. Using Eq. (1.3) it is possible to find value 2 for well-studied nerve fibers of a crab or a squid with d ~ 0 . 1 m m , r m ~ 1 0 0 0 O h m . c m 2, and r i ~ 100 Ohm-cm. The substitution of these values gives 2 ~ 0.2 cm. It means that at a distance of 0.2cm from the cell body, the amplitude of a nerve impulse must be almost three times less although the length of nerve fibers of these animals can be several centimeters. However it does not happen, and the nerve impulse propagates along the whole fiber without reducing the amplitude. This is why it happens. As we saw earlier, 2 0 - 3 0 m V increase of the intracellular liquid potential with respect to the outer one causes its further growth and the emergence of a nerve impulse in the given region of the cell. From our calculations it follows that if a nerve impulse with the amplitude 0.1 V appears at the beginning of a fiber, then at the distance 2 the voltage on a membrane would still exceed the resting potential by 30 mV, and a nerve impulse appears here as well; the same process takes place in the next segment of a fiber, and so on. Therefore, the propagation of an impulse along a nerve fiber can be compared with
_L V=Vo ex C~
l o
distance from voltage source F I G U R E 1 . 9 . Dependence of the voltage across a nerve fiber membrane on the distance from the voltage source with its positive electrode inside the fiber and the negative one outside of it in the proximity of point I = 0.
18
Chapter 1. Electricity Inside Us
flame spreading along Bickford's fuse; but it should be noted that with the former the required energy is supplied by the difference of concentration of potassium and sodium ions on each side of the membrane, whereas with the latter, it is supplied by the quick burning of easily inflammable insulation of
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the fuse. It is obvious that the greater the value of the space constant 2, the faster the nerve impulse can propagate. Since the values of r m and r i are almost the same in different cells and animals, it turns out that 2, and consequently the impulse propagation velocity, must depend mostly on the fiber diameter and grow proportionally with the square root of its value. This conclusion completely coincides with the results of experiments. A giant (about 0.5 mm in diameter) nerve fiber of a squid can show how nature has used the dependence of nerve impulse propagation velocity of the fiber diameter. It is well known that the squid running away from danger uses its "jet engine", forcing a great mass of water out of its mantle cavity. The muscular system contraction setting this mechanism in motion is started up by nerve impulses that propagate along several giant fibers. As a result, the high rate of response and the simultaneity of all this muscular system operation are achieved. Nevertheless, it is impossible to use such giant fibers in every region of a nervous system where a high rate of reaction and the analysis of the incoming information are required, as they would take up too much space. Therefore, for more sophisticated animal organisms, nature chose quite a different way of increasing the propagation velocity of excitation.
Nodes of Ranvier
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Figure 1.10 schematically shows a nerve fiber (cross section along the axis), most typical for our nervous system. This fiber is separated into segments, each being about I mm long. All such segments are covered by m y e l i n m a fat-like staff with good insulation properties. Between the segments, at a place about 10-3 mm long, the membrane of the fiber is in immediate contact with the outer solution. The area where the myelin sheath disappears is called the node of Ranvier. What should the structure of a nervous fiber entail? As it follows from Eq. (1.3) for length constant 2, when the unit area resistance (rm) of the
A M e n u f o r a Person C o n d e m n e d t o Death
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membrane grows, the value of 2, along with the impulse propagation velocity, should also grow. This enables the latter to become almost 25 times greater, compared to a nonmyelinized fiber of the same diameter. Besides, the energy loss for the propagation of excitation along a myelinized fiber is much smaller than that along a normal one since the total number of ions crossing the membrane is negligible in the former case. Thus, a myelinized fiber is a high-speed and economical communication channel in nervous system. The study of ionic channels of a membrane is a new and rapidly developing field of biophysics. Although nobody counted the number of the discovered ionic channels, apparently it must be approaching the first hundred. For many channels even the genes responsible for the synthesis of corresponding proteins have been identified. The opportunity to apply new physical and mathematical approaches has attracted many physicists to this estate of biologists. If you choose to turn to biology at this crossroad, the best guidebook to lead you through the jungles of ionic channels might be Bertil Hille's book Ionic Channels of Excitable Membranes (1992).
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A Menu for a Person Condemned to Death If you have thoroughly read everything so far, you undoubtedly deserve some rest. There are a lot of fairly interesting "semi-scientific" facts, and to
F I G U R E 1.1 0. Myelinized nerve fiber. The longitudinal section of the fiber is shown. The internal contents of the fiber, shaded with dots, is enclosed with an excitable membrane.
20
Chapter 1. Electricity Inside Us
study them helps you relax a great deal. As a rule, many of them begin with "It is well known that...". Well, it is well known that a certain poison, tetrodotoxin, C11H1708N3, completely blocks sodium channels. This substance seems to be the most low-molecular of all the known toxins of protein nature. This poison, which plugs a sodium channel like a cork plugs a bottle, was extracted for the first time from Fugu fish, or puffer fish, which inhabit the Sea of Japan. The poison was named after the Latin term for the fish of the Tetraodontidae family to which the puffer fish belongs. Up to now, eating fugu's entrails has been considered in Japan to be a particularly refined way of suicide. Between 1927 and 1949, about 2700 men died of fugu poisoning. Selling this fish is forbidden in some regions of Japan; where it is allowed, only certified cooks are allowed to cook fugu. Surprising as it may seem, the dish cooked with this fish is an exquisite delicacy of Japanese cuisine, despite the fact that some unfortunate gourmets died soon after. Though fugu has been notorious for thousands of years, there are still plenty of those who want to taste this dish. Apparently, one of the first Europeans who had the privilege of tasting fugu was the English traveler James Cook, who was informed by the aborigines that this dish was p o i s o n o u s ~ b u t not until he had eaten it. People say that when you are eating fugu, you don't only taste it ~ evidently the presence of what is left of tetrodotoxin in the dish gives a pleasant tingling and a warm feeling in the limbs, as well as euphoria. However, if you carelessly consume this dish, you can easily die because of the cessation of breathing. Puffer fish uses its poison to scare predators away. In its skin, glands secrete tetrodotoxin when the fish is irritated by something. Tetrodotoxin can be found in the liver of this fish as well, and the scientists have yet to answer the question of why the nervous system of the fish remains immune to such potent poison. The presence of tetrodotoxin was detected not only in fugu. It is also synthesized in certain species of salamanders, frogs, gastropods, crabs, and starfish. Some species of octopuses have tetrodotoxin secreted by glands located in suckers, so a "handshake" from such a creature is a real danger even for a human being. The only thing in common for different poisonous animals such as fugu, salamanders, frogs, and octopuses is that they all have
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Living Electricity Around Us
zyxwv zy 21
tetrodotoxin contained in their spawn. Thus, it is obvious that the main function of the poison is to protect the offspring. People learned how to use tetrodotoxin long ago. This deadly poison (it is 1000 times stronger than potassium cyanide) is mentioned even in fiction. For example, Agent 007 James Bond, a well-known character of British author Ian L. Fleming, was nearly poisoned by it. Unfortunately, terrorists are using it now, and it is by no means a tale. This poison has an interesting property that is appealing to unscrupulous people. If the dose of tetrodotoxin is slightly less than a lethal one, a person gets into a state that absolutely looks like death. However, unlike real death, this state is reversible, and in a few hours a "dead" person comes back to life. Those who would like to know more about tetrodotoxin, fugu, poisoned dishes, etc., can read a very interesting article by E A. Fuhrman (Fuhrman, 1986), where you can find a lot of scientific and semi-scientific facts.
Living Electricity Around Us We have discussed why potential difference on the membrane of living cells appear, and have examined the process of the propagation of impulses along a nerve fiber. All the electric phenomena we are speaking about take place only on the cell membrane. But what was it that E. du Bois-Reymond registered in 1843 with the help of a simple galvanometer connected to a nerve? Since microelectrodes were not used until a hundred years later, it means that his galvanometer registered an electric field in the solution surrounding the nerve. Examining the cable properties of a fiber, for the sake of simplicity we considered the outer solution of an electrolyte to be equipotential. Indeed, the voltage drop in the outer solution should be hundreds of times less than that inside a fiber because of much larger dimensions of the outer conductor (solution). Nevertheless, under sufficient amplification, an electric field can always be detected around an excited cell or organ, especially when all the cells of an organ are excited simultaneously. Our heart is such an organ in which all the cells are excited almost simultaneously. Like all other internal organs, it is all surrounded with electroconductive medium (the blood resistivity is ~ 100 Ohm.cm). Thus, at each excitation, the heart surrounds
22
Chapter 1. Electricity Inside Us
itself with an electric field. Therefore, a cardiologist, by measuring and analyzing the potential differences between different points of the body that appear in systole (electrocardiogram), sees how the heart works. In 1924, a Dutch physician Willem Einthoven was awarded the Nobel Prize for the introduction of the cardiograph technique into the diagnostics of cardiac diseases. People knew for a long time that fish can be a source of electric discharges. You can see an electric catfish on ancient Egyptian tombs, and "electrotherapy" with the help of this fish was recommended by an ancient Greek physician Galen (130-200 A.D.). Another ancient doctor who treated Roman emperor Claudius (first century A.D.) prescribed electrical treatment in the following way: "A headache, even if it is chronic and unbearable, vanishes, if a live black ray is placed on a painful spot and is kept there until the pain disappears." Gout was treated in the same way: "With any type of gout, when pain starts, a live black ray should be placed under the feet. Meanwhile the patient should stand on wet sand washed by seawater and remain so until his leg below the knee goes numb." At the same time people noticed that the shock of a ray could pass through iron spears or sticks moistened with seawater and thus affect people who have no immediate contact with the ray. Some fish are able to produce very strong discharges, immobilizing (paralyzing) other fish and even animals of a human size. Ancient Greeks, who believed that an electric ray could "enchant" both fish and fishermen, called it narke. This Greek word means a making rigid, or striking fish. The word narcotic is of the same origin. Before the electric theory appeared, the theory that explained the shock of a ray as a mechanical effect was considered most efficient. Among the protagonists of this theory was French natural scientist R. Reaumur, whose name was given to one of the temperature scales. Reaumur assumed that a ray produces a shock by a muscle that can contract at a high rate. This is why if you touch such a muscle, a limb can go numb for some time, as it happens, for example, when you hit your elbow. It was not until the end of the eighteenth century that the experiments which revealed the electric nature of the shock produced by a ray were carried out. A Leyden jar, the main electric capacitor of the time, played a certain part. Those who experienced the discharges of the Leyden jar and a ray claimed that the two were very similar in their effect. Like the discharge
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Living Electricity Around Us
zyxwvzy 23
of a Leyden jar, the shock of a ray can simultaneously affect several people holding one another by hand, as long as one of the hands touches the ray. The last doubts regarding the nature of the shock produced by a ray disappeared in 1776, when it was demonstrated that under certain circumstances, this shock could bring about an electric spark. For this purpose two metal wires with the tiniest possible air gap between them were partially submerged into a tank where the fish swam. A brief closure of the wires attracted the fish's attention, and it moved close to the wires and produced an electric shock; sometimes at this very moment sparks flashed between the wires. For the sparks to be more visible, the experiments were carried out at night. Soon after the experiments were over, some London newspapers started advertising a shake-up with a discharge of an electric fish for only two shillings and six pence. Benjamin Franklin, one of the authors of the theory of electricity, supported electric treatment. That is why the use of static electricity in medicine is still called franklinization. By the early nineteenth century people already had known that the discharge of electric fish can pass through metals, but not through glass and air. In the eighteenth and nineteenth centuries physicists often used electric fish as a source of electric current. For example, Faraday showed while studying the discharges of an electric ray that the animal electricity did not dramatically differ from other kinds of electricity, which then were considered to be five: static (produced by rubbing), thermal, magnetic, chemical, and animal. Faraday believed that if people understood the nature of animal electricity, it would be possible "to convert the electric force into the nervous." The strongest discharges are produced by the South American electric eel. They can be as strong as 500-600 V. The impulses of an electric ray can have voltage of up to 50V and discharge current more than 10A so that their power often is more than 500 W. All the fish that produce electric discharges use special electric organs. In high-voltage electric fish, such as marine electric ray, freshwater electric eel, and catfish, these organs may take up a considerable part of the animal body volume. For example, in an electric eel they are located along the whole body, which is about 40% of the total volume of the fish. The diagram of an electric organ is shown in Figure 1.11. It consists of electrocytes m much flattened cells packed into stacks. The endings of nerve fibers reach up to the membrane of one of the two flat sides of an electrocyte
zyxwv
24
FIGURE 1 . 1 1 .
Chapter 1. Electricity Inside Us
Diagram of an electric organ ofafish.
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(innervated membrane); there are no endings on the other side (noninnervated membrane). The electrocytes are collected in a stack so that they face one another with opposite membranes. At rest, the potential difference at both membranes of an electrocyte is the same (about 80 mV); the inner medium of a cell bears a negative charge with respect to the outer. Consequently, there is no potential difference between the outer surfaces of both membranes of the electrocyte. When an impulse approaches the electrocyte along a nerve (such impulses arrive at all electrocytes of an organ almost simultaneously), the nerve endings secrete acetylcholine. Acting upon the innervated membrane of the electrocyte, it increases the permeability of the membrane for sodium ions as well as some others; this results in the excitation of the membrane. During the excitation, the voltage across the innervated membrane of an electrocyte changes its sign and reaches ~ + 70 mV, whereas the potential difference between the outer surfaces of the same electrocyte becomes ~ 150mV. Since electrocytes are placed in a stack, the voltage between the end cells in the stack will be proportional to their number.
Electrical Compass
25
The number of electrocytes in one stack of the electric organ of an electric eel can be as many as five to ten thousand, which explains the high discharge voltage in these species. The magnitude of the discharge current is determined by the number of such stacks in the electric organ. There are 45 stacks of this kind on every fin of an electric ray, and an electric eel has about 70 of them on every side of the body. To prevent the current generated by the electric organ from passing through the fish itself, the organ is covered by insulating tissue with high resistivity, and it contacts outer medium only.
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Electrical Compass Interacting with the earth's magnetic field, various kinds of ocean and sea currents generate electric fields. Being highly sensitive to external electric fields, sharks and rays use them to find their way drifting along with these currents over boundless oceans. When the animals move with respect to the water, their motion is accompanied by the appearance of an electric field that serves as a kind of electromagnetic compass. Is it really so? Let us see what happens in the coordinate system that swims along with a shark through motionless water. If the shark is assumed to be moving rectilinearly and uniformly the reference system we select will be inertial. It means that according to the principle of independence (equivalence) it does not matter in what coordinate system we consider the forces acting upon the shark: the resting (R) one or the one that swims together with the shark (S). However, in system S, the shark is not moving, so this motionless shark would seem incapable of establishing an electric field. Can it be the very case when the principle of equivalence is violated? Of course not. Let's consider the motion of charged bodies in magnetic field in detail. It is well known that a charge e moving at the velocity V in the magnetic field with magnetic flux density B, is acted upon by Lorentz' force r
:
zyxwvutsrqponmlkjih e[VB]
In other words, a charge moving in a magnetic field establishes an electric field with strength E = [VB]. However, if we consider the coordinate system moving together with the charge, the Lorentz' force will not act upon the charge, since in the new system it is at rest. Therefore, we find it necessary to
26
zy zyxw
C h a p t e r 1. Electricity Inside Us
postulate the existence of an electric field with the strength [VB] in a new coordinate system. Hence, when passing over from an inertial coordinate system to another system moving with respect to the first one at velocity V, we should change the value of the electric field strength by [VB]. Now, let us return to our sharks. Let one of them swim at the horizontal velocity V relative to motionless water in the earth-bound coordinate system. N o w it is obvious to us that the interaction with the earth's magnetic field generates an electric field. The vertical component of the latter is equal to [VBh] where Bh is the vector of the horizontal component of the magnetic field. Thus, a shark swimming in the earth's magnetic field surrounds itself with an electric field and is a source of the electromotive force (Figure 1.12). Measuring the strength of the field, the shark can obviously evaluate its speed with respect to the earth. Cartilaginous fish (like a shark) are very sensitive to electric fields, and their reaction is demonstrated in the relation to the gradients of the potential below 5 nV/cm in the frequency range from 0 to 8 Hz. A number of special experiments were carried out where nocturnal ocean predators were led to an electrical model of a prey which established an electric field with the gradient of 5 nV/cm. When it was accompanied by the smell of a typical prey, the sharks hit the model quickly and accurately from a distance of up to 0.5m.
F 16 U R E 1.1 2. Shark that is swimming eastward at a horizontal velocity V. Shown around the shark are the electric field lines.
Electrical Compass
27
High sensitivity of cartilaginous fish to the electric field is explained by the fact that they have special electroreceptors, the ampullae of Lorenzini, each of which consists of a cross-sectionally small, but sufficiently long pore that is filled with jelly-like matter and ends with the receptor cells. The sensitivity of this live voltmeter was increased by the walls of the pore leading to receptor cells being made of a material with a much higher resistivity than the jelly-like matter. Among the electric fish there are those that use their electric organ to look for the prey rather than for attack or defense. These are sharks, lampreys, and some catfish having very high sensitivity to an external electric field. A shark swimming in the open sea is known to be capable of finding sandcovered flatfish, an ability produced exclusively by the perception of bioelectrical potentials that appear when the prey is breathing. The electric organ of fish with the high sensitivity to an external electric field operates at a frequency of several hundred Hz and can generate oscillations of potential difference (about several Volts strong) on the surface of the animal body. As a result, an electric field appears which is picked up by electroreceptors, the ampullae of Lorenzini, the latter sending nerve impulses to the animal's brain. Since the conductivity of the objects in the water around the fish differs from that of the water itself, the electric field is distorted (Figure 1.13). The field distortions can be used by fish to take bearings in turbid water and to find quarry (von der Emde et al., 1998). It is fairly interesting to note that almost all fish that use their electric organs to find their way swimming keep their tails practically motionless. Unlike other fish, they move in water due only to undulatory movements of their well-developed lateral (electric ray) or dorsal (Nile pike) fins. Since the electric organs of these fish are located in the tail part of the body and the electroreceptors are in the middle, the strength of the electric field around of the receptors depends only on the conductivity of outer solution. Japanese researchers established that immediately before a strong earthquake the catfish becomes unusually sensitive to weak mechanical disturbances, provided the aquarium is linked by channels with a natural water reservoir. This can be attributed to the potential differences that appear between points of the earth's crust before an earthquake and are perceived by the catfish. The strength of electric fields frequently emerging eight hours before the earthquake can reach 0.3 mV/m, which exceeds the sensitivity level of the fish more than a hundred times.
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28
C h a p t e r 1. Electricity Inside Us
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F I G U R E 1.1 3. Distribution of equipotential lines of the electric field around a fish with an electric organ (its position in the tail part is shown by an arrow). The shaded ball-shaped object has a greater conductivity than the ambient one. It is clear that the electric field strength near the fish's lateral surface on the side of the object is different from that on the opposite side.
Interestingly, about two thousand years ago a legend was circulating in Japan, which said that the catfish was able to go underground, and by moving, cause earthquakes. However, it was not until the twentieth century that the behavior of animals before an earthquake attracted the attention of Japanese seismologists. Today, biological methods for predicting earthquakes are rapidly being developed. It is well known that the fish in an aquarium with a direct current running through it swim in the direction of the anode and suddenly stop short of it, paralyzed. The voltage drop across the fish length must be about 0.4 V. After the current is turned off, the fish may "come to their senses" and start swimming again. If the voltage drop is increased to 2 V, the fish become rigid and soon die. The attractive force of the anode is successfully employed in electrical fishing. At the same time, the electric current scares away the fish that is more sensitive to it (e.g., sharks). Scientists carried out a series of experiments with a so-called electric fence to check its effect on sharks. It has
Electricity in Plants
zyxwvuzy 29
been established that the current running between two electrodes acts as a barrier for sharks and is practically imperceptible for a nearby human.
Electricity in Plants Plants are fastened in the soil by their roots and, therefore, often are considered a model of immobility. The notion is not entirely correct since all plants are capable of slow growth twists necessary to adapt to lighting and the direction of the force of gravity. Such movements are due to the nonidentical growth rate of different sides of an organ. In addition, plants move periodically during the day folding and unfolding their leaves and flower petals. Some other plants are capable of even more noticeable motion and respond with rapid movements to a variety of external factors: light, chemical agents, touch, vibration. Such sensitivity helped mimosa become proverbial: you only have to touch it slightly for its fine leaves to fold and for the main stem to droop. Various insectivorous plants and tendrils of lianas are also capable of fast response. How can such rapid movements occur in plants? What is crucially important here are the electric processes taking place in cells. A cell of a plant as well as a nerve or muscle cell of an animal has proved to have a potential difference of a b o u t - 1 0 0 mV between the inner and outer surfaces of a membrane. The potential difference is affected by the different ion composition of intra- and extra-cellular media, as well as the nonidentical permeability of the membrane for the ions. Under exposure to the external irritators listed earlier, the membrane of a plant cell is excited: its permeability for one of the cations (as a rule, for calcium) grows. As a result, the voltage across the membrane goes down to almost zero, but soon recovers its initial value. The duration of this action potential can be as long as 20-30 seconds (Figure 1.14), and can propagate from one cell to another in the same way a nerve impulse does, but at a noticeably slower speed. For example, the action potential propagates along a mimosa stem at a velocity of about 2 cm/s and along a leaf of insectivorous plant Venus flytrap at 10 cm/s. The recovery of the initial potential difference across the membrane of a plant cell after its excitation occurs due to the opening of additional potassium membrane channels that were closed in the state of rest. The increase of potassium permeability of the membrane leads to the outflow of
30
C h a p t e r 1. Electricity Inside Us mV 10 I
o') 0 > c.-
15 '
time, sec
zyxwvuts zyxwvutsrq -50
-~ -100 E
E
-150
FIGURE
1.14.
Action potential o f a p l a n t c e l l .
a certain number of potassium ions from the cell (there is more potassium inside than outside) and the recovery of the potential difference. The outflow of potassium ions from a plant cell under excitation is believed to happen not only due to the increase of the potassium permeability of its membrane, but also to other reasons not well studied. Thus, every excitation of a plant cell is accompanied by a short decrease of the concentration of potassium ions inside the cell and its increase outside, which underlies the motional response of the cell. To understand the implications of the changing concentration of ions inside a plant cell, we can carry out the following experiment. Take some common cooking salt and put it into a small bag impermeable for the salt but permeable for water (e.g., cellophane). Place the bag with salt into a saucepan with water. You will soon see the bag swell, because the water would infiltrate the bag in order to balance the osmotic pressures inside and outside of the bag, both proportional to the concentration of dissolved ions. As a result, the growing hydrostatic pressure inside the bag may cause it to burst. The living vegetable cells are concentrated solutions of salts, enclosed within a membrane, highly permeable for water. Once in contact with common water, the cells swell so much that the pressure inside them could rise up to 5 - 1 0 6 Pa. The magnitude of the intracellular pressure and the
31
Electricity in Plants
FIGURE Figure
1.15.
zyx
The mechanism of motional activity of plants.
Left: leaf stem in the state of rest; right: leaf stem under excitation.
extent of the plant cell swelling depend on the concentration of ions dissolved in it. For this reason, the decrease of the concentration of potassium ions inside a cell during excitation is accompanied by the lowering of intracellular pressure. Now imagine that some leaf stem consists of two cell groups arranged lengthwise (in Figure 1.15 the cell groups are separated with a dashed line) and the excitation spreads to the lower cell group only. Under excitation, the lower part of the stem collapses in, while its swollen upper part bends the stem. The same mechanism can work in other parts of a plant. Thereby, as is the case with animals, the electric signals that propagate along the plant provide an important means of communication between different cells, thus coordinating their activity.
This Page Intentionally Left Blank
Heart Pulse
In primitive society, as a man was cutting animal carcasses, he must have paid attention to the muscular sack in the middle of the animal chest. The "sack" could contract rhythmically for several minutes in the body of a listless prey. An apparent simultaneity of death and a heart arrest must have resulted in the theory that a man's heart is identified with his soul. That is why one of the earliest literary texts, Odyssey, by the Greek epic poet Homer, contains such word combinations as "grieve with one's heart, .... fill the heart with courage, .... heart's will," and so on. Another great Greek, Aristotle (384-322 B.C.), the founder of modern science, believed that the heart was the seat of thought. The studies of the function of the heart were not to begin until much later, though. It was only in 1628 that the English physician William Harvey (1578-1657) published his famous De motu cordis, in which he expressed the conclusion that the heart served as a pump pushing the blood through blood vessels. To prove that blood circulated (flowed in a circle), Harvey merely had to show that a large quantity of blood passed out of the heart m roughly between 10 and 41 pounds of blood in half an hour m and that this quantity is greater than that which can be drawn from the body, or which can be obtained from processing food and liquid. He thus disposed of the
z
zyxwv 33
zy
34
zy zy
Chapter 2. Heart Pulse
Galenical tradition according to which blood was considered to be made de novo in the liver, and to flow and ebb in the arteries. Harvey arrived at a conclusion that the same blood repeatedly returns to the heart, the latter acting as a hydraulic pump. To model the heart function, rather than using a pump with an ordinary valve, Harvey chose a special pump utilized at the time to drain water from mines. Harvey's discovery provoked a long and heated discussion. Even Rene Descartes, an outstanding French physicist and mathematician, while agreeing with Harvey's blood circulation theory, did not share his opinion on the role of the heart in this process. Descartes considered the heart to be something that could nowadays be compared to a steam engine or even to an internal combustion engine. He considered the heart to be the source of heat that warmed the blood as it passed through this organ, thereby keeping up the heat in the whole body. In his opinion, this warmth was concentrated in the heart walls from the very beginning of the life. Thereby, when blood entered the heart cavity, it boiled up in it at once and further on, in the form of steam, got into a lung, which was constantly cooled by the incoming air. In the lung, the steam "condensed and turned back into blood." This is only a fraction of the fascinating story about the changes of people's views on the role of the heart in our organism (for review, see Leake, 1962).
Arteries, Blood, and Erythrocytes Now we know that our heart is a pump operating in the impulse mode at a frequency of about 1 Hz. During each impulse, lasting for approximately 0.25 seconds, the heart of an adult is able to push about 0.1 L of blood from itself into the aorta. The blood moves from the aorta into the narrower vessels, the arteries, which deliver the blood to the periphery. The origin of the word artery is fairly interesting m i t derives from the Greek word windpipe. It is known that the greater part of a dead animal's blood is in the veins, the vessels through which the blood returns to the heart. That is why corpses have swollen veins and collapsed arteries. If such an artery is incised, it immediately assumes a cylindrical shape as it is filled with air. This, apparently, is the reason why a blood vessel got such an odd name. The blood is a suspension of various cells in the aqueous solution. The red
zyxwv zyxwvutsr
Arteries, Blood, and Erythrocytes
35
cells (erythrocytes) constitute the major part of blood cells. They take up about 45% of its volume, and each cubic millimeter of blood contains approximately 5 million erythrocytes. The volume occupied by the rest of the blood cells does not exceed 1%. The inside of erythrocytes holds hemoglobin, a complex of the protein globin with the organic group (heme), the latter containing an atom of iron. It is hemoglobin that gives the erythrocytes (and all the blood) their red color, whereas hemoglobin's ability to reversibly bond with oxygen insures the high oxygen capacity of blood1. A liter of blood, free of erythrocytes, can bind only 3 mL of oxygen (at the atmospheric pressure), whereas a liter of normal blood can bind 200 mL. This enables the blood to perform its main function of supplying the cells of an organism with oxygen. Erythrocytes are very flexible concavo-concave disks (Figure 2.1) and consist of a very thin (7.5nm) membrane and liquid contents, a nearsaturated hemoglobin solution. Despite the fact that the diameter of erythrocytes is about 8 #m, they can pass unscathed through the capillaries of 3-/lm diameter. During this passage they become markedly deformed, resembling a parachute canopy, or rolled up into a pipe (see Figure 2.1 (b)). As a result, the area of contact of the erythrocyte with the capillary wall increases (as compared to the movement of a nondeformed erythrocyte) and so does the gas exchange rate. How can we explain the ability of erythrocytes to deform easily? A body of a spherical shape can be shown to have the minimal surface area for the given volume. It means that, if an erythrocyte were a sphere, the area of its membrane would grow under any deformation. Therefore, the flexibility of these spherical erythrocytes would be limited by the rigidity of their cell membrane. Since a normal erythrocyte is nonspherical, it can deform without concurrent changes in the membrane surface area, and can readily assume all kinds of shapes. There is a blood disease, known as hereditary spherocytosis, whereby erythrocytes are of spherical shape with a diameter of about 6/~m. The membrane of such erythrocytes in their movement through thin capillaries is
1 One of those who studied the mechanism that enables the release of oxygen from blood into body tissues was Christian Bohr, the father of the well-known physicist Niels H. Bohr. The dependence of the oxygen capacity of blood on the hydrogen-ion concentration is still referred to as the Bohr effect.
36
Chapter 2. Heart Pulse
zyxwvu
FIG U R E 2 . 1 . Erythrocyte: (a) undeformed (left: top view; right: side view); (b) assuming the shape of a pipe or parachute canopy during the passage through fine capillaries.
constantly in a state of stress and often ruptures. As a result the number of erythrocytes in the blood of these patients is lowered, and they suffer from anemia. A great number of people become deaf with age. Although only about 12% of the total adult population experience this gradual advent of deafness, its true cause could not be identified for a long time. It was only in the 1980s that scientists' attention was drawn to unusual properties of erythrocytes in deaf people. This conclusion was reached while measuring the viscosity of blood in normal and deaf patients with rotational viscosimeters, which make it possible to examine the dependence of the viscosity of blood on a velocity gradient (rate of shear).
Arteries, Blood, and Erythrocytes
zyxwv 37
The viscosity of blood, like that of most suspensions and solutions (in contrast to pure solvents) is dependent on the rate of shear (Figure 2.2). For this reason, the blood is termed as non-Newtonian liquid. This dependence is due to the fact that not only the blood plasma, but also erythrocytes with their relative orientation and shape and changeable during the motion, participate in the transfer of shear stress from layer to layer along a perpendicular to the flow velocity. Since erythrocytes are not spherical, they may become oriented when the suspension is sheared. If the fiat surface of the erythrocyte disc is parallel to the vessel wall, there will be a minimum disturbance to the lines of flow, and the presence of the cell will have the least effect on the viscosity of the system. Direct microscopic observation of suspension of erythrocytes, flowing through a tube, has shown that with increase in the rate of flow, the cells become increasingly oriented along the axis of the tube. Figure 2.3 shows schematically how the increase in shear stress can bring about the orientation of erythrocytes in the moving blood flow (a) and their deformation (b). It is probable, therefore, that orientation effects contribute
10 3 -
o
10 2
-~
10-
zyxwvu
m
I
0
10 -2
I
10-1
I
I
1
10
I
10 e
I
10 3
rate of shear, s-1 FIG U R E 2 . 2 . Dependence of relative viscosity of human blood on rate of shear. (From Gabelnick, H.L., and M. Litt (Eds.) Rheology of Biological Systems, 1973. Courtesy of Charles C. Thomas, Publisher, Ltd.: Springfield, IL.)
38
Chapter 2. Heart Pulse
zyxw
F I G U R E 2 . 3 . Schematic presentation of orientation of ellipsoidal (a) and deformation of spherical (b) cells in the flow. Left: stationary liquid; right: the same cells in a moving liquid with transverse velocity gradient. The vector field of velocities is schematically shown with arrows.
to the reduction in apparent viscosity of blood with increase in the rate of shear (Figure 2.2). By comparing the viscosity values at very small and large values of rate of shear, it is possible to calculate certain deformation characteristics of erythrocytes. It turns out that the rigidity of erythrocytes in deaf people is much higher than in healthy ones. High flexibility (small rigidity) of erythrocytes is known to be a necessary condition of their penetration into the finest capillaries. Hair cells of cochlea, which perceive sonic vibrations and convert them into a sequence of nerve impulses, are supplied with blood through capillaries with a diameter of 4-5/~m. At the same time the diameter of the disk-shaped erythrocytes amounts to 7-8/~m. Therefore, it is only the high elasticity of erythrocytes (their ability to roll themselves up into a pipe) which helps them literally push through such narrow capillaries near hair cells. Several different experimental approaches have been developed to assess red cell deformability. In some techniques, the transit times of individual
Arteries, Blood, and Erythrocytes
zyxwv zy 39
erythrocytes across a membrane containing cylindrical micropores are measured electrically (Frank and Hochmuth, 1988). In filtration tests, flow rates of red cell suspensions through membranes are determined (Nash, 1990). Use of micropore transit to estimate red cell deformability has the advantage that the pore diameters can be chosen to correspond to the diameters of the smallest microvessels ranging from 3 to 7/tm. The complexity of the deformations undergone by red cells makes it difficult to use a mathematical model to simulate the cells' transit across a membrane using a mathematical model. However, recently Secomb and Hsu (1996) described a model that enables the analysis of the red blood cell motion through cylindrical micropores. According to the model, both the transit time and the blood filterability are sensitive to the erythrocyte membrane shear viscosity. However, it should be noted that an axisymmetric model proposed by the authors may prove inadequate for actual cell passage across a pore. It is believed that in deaf persons the capillaries near hair cells are clogged with stuck erythrocytes, unable to roll up into a pipe. As a result, these cells gradually die because of blood supply failure, so that deafness occurs. A sudden-onset deafness is often of the same nature as that developing over time in middle-aged people--stuck erythrocytes in fine capillaries of cochlea. As was found by Hall et al. (1991), the filterability of the red blood cells is significantly impaired in patients with the sudden deafness, which suggests that alterations in the cochlear microcirculation are linked to erythrocyte resistance to transient deformation. However, sudden deafness may be unrelated to the change in the erythrocyte rigidity and, therefore, sometimes yields to efficient treatment. The blood of a patient is temporarily thinned in order to lower the concentration of erythrocytes in it. As a result, the motionless line of erythrocytes in the finest capillaries of cochlea is resolved and the patient regains his or her hearing. One more practiced technique to estimate erythrocyte deformation is the electric field method presented by Engelhardt and Sackman (1988). A highfrequency electric field polarizes cells suspended in a low ionic strength solution in a frequency range where the Maxwell-Wagner polarization (Pohl, 1978) is effective (0.1-10MHz), and thus generates within this frequency range a constant uniaxial force in the direction of the electric field strength. The cells respond to that force by elongation, which is mainly
zyxwvu
40
Chapter 2. Heart Pulse
elastic shear deformation (deformation under constant volume and surface area).
Velocity of Pulse Wave The blood motion across the vessels is a rather complicated process. The wall of the aorta, as well as the walls of all other arteries, is highly elastic: its Young's modulus is 105times smaller than that of metals. Therefore, when blood enters the aorta, the latter starts expanding until the blood inflow stops. After this, the elasticity of the expanded aorta wall, seeking to bring the aorta back to its initial dimensions, squeezes the blood out into the artery section, more distant from the heart (the reverse flow is hindered by the aortic valve of the heart). This section of the artery becomes stretched and everything is repeated from the beginning. Were the deformation of an artery wall to be recorded simultaneously at two nonequal distances from the heart, it would turn out that the artery deformation reached its maximum values at different moments of time. The more distant from the heart, the later the vessel deformation reaches its peak value. Thus, after each systole a wave of deformation runs along an artery in the direction from the heart to the periphery, in much the same way as waves propagate along a tight string or along the water surface from a stone dropped into it. And if a finger is placed on an artery, which is close to the body surface (e.g., near a wrist), the finger will sense the waves in the form of pushes (pulse). Here, we should note that the velocity of propagation of the blood vessel deformation wave may significantly differ from that of the compression wave in blood. The latter is, obviously, equal to the velocity of propagation of sound and amounts to several hundred meters per second, whereas the deformation waves cover no more than several meters a second. People had learned to measure frequency, rhythm, and repletion (amplitude) of pulse long before its origin became known. The first references to the measurements of pulse in humans date back to the third millenium B.C., when physicians used the registration of pulse for diagnostic purposes. The teaching on pulse became one of the major accomplishments of diagnostics in ancient China. Their concept, elaborated in the course of
zy
Velocity of Pulse Wave
zyxwvu 41
many years of cardiac pulse observations, was that all processes in an organism should somehow affect the shape of a pulse wave. They studied pulse at several points rather than at a single point on a wrist (as we do now). Sometimes there were as many as ten such points. Chinese physicians drew distinctions between 28 types of pulse: superficial, deep, rare, frequent, thin, excessive, free, tough, strained, and so on. Thousands of years before the scientific validation of the blood circulation theory, they had already assumed that it was the pulse that determined the "blood circle." The ease of pulse measurement (no instruments are needed except for a stopwatch) makes it one of the main indicators of one's state of health even at present. The propagating wave of deformation of the artery walls got to be known as a pulse wave. Measuring the velocity of pulse wave propagation had met no success untill the early twentieth century, when the first inertialess recording devices appeared. The value of the velocity lies, as a rule, between 5 to 10 m/s and more, which is 10 times greater than the average speed of the movement of blood along blood vessels. The velocity of propagation of a pulse wave has proved to be dependent on the elasticity of an artery wall and, therefore, could be an indicator of its state in the diagnosis of various diseases. A mathematical expression for velocity 0 of the propagation of pulse waves in arteries is easily derived if we consider wave propagation in an infinitely long tube, the walls of which are completely elastic; that is to say, the wall material does not show any elastic hysteresis or internal friction, and its stress-strain relationship obeys the law of Hooke. Following is the well-known M o e n s - K o r t e w e g equation:
zyxwvuts 02 - E a / p d
(2.1)
where E is the Young's modulus of elasticity for artery wall material; a is the artery wall thickness; p is the density of blood; and d is the artery diameter. The substitution of a / d - 0.1, E - 106 N/m 2 and p - 103 kg/m 3 into Eq. (2.1) yields the value 0 ~ 10 m/s, which is close to the average value of the velocity of propagation of pulse wave, measured experimentally. Anatomical studies show the quantity a/d to vary a little from one person to another and to be practically independent of the artery type. Therefore, in view of the constancy of a/d, the pulse wave velocity can be considered to
42
Chapter 2. Heart Pulse
change solely with changes in the elasticity of an artery wall, its Young's modulus. With age, as well as in the case of diseases accompanied by increased E of artery walls (hypertension, atherosclerosis), E may grow almost twofold compared to the norm. This makes it possible to use the measurement for diagnostic purposes. It is interesting to note that Eq. (2.1) for the velocity of propagation of the pulse wave in the arteries was first derived by the famous English scholar Thomas Young in 1809. Young is remembered mainly as the creator of the wave theory of light, and also because the elasticity modulus of materials is named after him. He was also the author of the classical works on blood circulation theory, including those on propagation of pulse wave in arteries. He was truly an extraordinary personality. He could read at the age of two, and at 14 had a good command of ten languages, played nearly every musical instrument, and had the skills of a circus performer. During his entire life he combined two professions, that of a practicing physician and of a physicist.
Reflection of Pulse Waves Like any waves, the pulse waves in arteries are capable of reflecting from the sites where the conditions of their propagation change. Such sites for the pulse waves are the regions of artery branching (Figure 2.4(a)). The wave reflected from the branching region is superimposed on the primary one, which makes the curve of blood pressure changes in a vessel bimodal (Figure 2.4(b)). It is possible to estimate the distance between the point of the recorded pressure and the site of branching by measuring the interval between two maxima on the pressure curve and the given velocity of propagation of a pulse wave. Sometimes the pressure curve exhibits more than two maxima, which is indicative of the multiplicity of the pulse wave reflection process. The reflected pulse wave, like the primary one, is accompanied by the arterial wall deformation. However, whereas the elastic energy of the wall deformation caused by the propagation of the primary wave is later converted into the kinetic energy of the blood moving from the heart to the periphery, the reflected wave in fact obstructs a normal blood flow. For this
zy
43
Reflection o f Pulse Waves
zyxwvu
F I 6 U R E 2 . 4 . Emergence of reflected pulse wave at the site of artery branching. (a) section of branching artery; (b) arterial pressure change in the presence of a reflected wave.
reason, the pulse wave reflection interferes with the normal functioning of our circulatory system. It can be shown (Hardung, 1962) that under certain assumptions, the amplitude, Pr, of pressure changes in the reflected pulse wave depends on the parameters of branching and the amplitude, Pi, of the primary (incident) pulse wave:
zyxwvuts
Pr(SA/OA + SB/OB + S c / O c ) -- Pi(SA/OA -- SB/O B -- S c / O c )
(2.2)
44
Chapter 2. Heart Pulse
where 0A, 0B, 0C are the velocities of propagation of a pulse wave along arteries A, B, and C, and SA, SB, and Sc are the cross-section areas of the arteries. It can be concluded from Eq. (2.2) that there is no reflected wave if the factor in the parentheses in the right-hand part of the equation is zero. If the velocity of the pulse wave propagation is considered to be the same beyond the branching site since, as a rule, aid and E remain unchanged, there will be no reflected wave provided:
zy
zyxwv
SA -- SB + Sc
(2.3)
Thus, in order to have no reflected waves at the sites of arterial branching, it is necessary that the sum total of the cross-section areas of arteries remain unchanged beyond the branching. In other words, to minimize the energy loss due to reflected waves in the circulatory system, shown schematically in Figure 2.5, the following rule should be observed: R ~ - S U M (Ri2K), i - - I . . . N K
(2.4)
where R 0 is the aorta radius and RiK is the radius of one of N n vessels, which are K branchings away from the aorta. Note that the greater part of branchings of major arteries satisfies, to
F I G U R E 2 . 5 . Scheme of arterial bed. Branching numberk=0corresponds to the aorta; k = N corresponds to capillaries.
Equilibrium of the Blood Vessel Wall: Aneurysm
zy zyxw 45
some extent, Eqs. (2.3) and (2.4), which requires the constancy of the crosssection of the blood vessel bed before and after the branching site. In some cases, the equation does not hold, and it leads to this.
Equilibrium of the Blood Vessel Wall" Aneurysm After each systole the blood pressure in the aorta increases, its walls stretch, and a pulse wave propagates along them. This rhythmic extension recurs about 100,000 times a day and approximately 2.5 billion times throughout life. In principle, the arterial wall structure is capable of withstanding these rhythmic hydraulic shocks. Sometimes, however, the aorta wall gives way and starts expanding to form an aneurysm. Once started, the expansion tends to grow on and on, so that the aneurysm finally bursts, causing death. The probability of aneurysm occurrence increases with age. The typical place for an aneurysm to develop is the abdominal part of the aorta, a little above its branching. The aneurysm is believed to appear in the region of pulse wave reflection from the site of aorta branching. As shown in Eq. (2.2), the amplitude of the reflected wave is proportional to the difference between the cross-section area of a vessel before the branching and the total cross-section area beyond it. The difference grows with age due to narrowing of the peripheral arteries. As a result, the amplitude of the reflected pulse wave increases, causing a greater extension of aorta walls in that place. The growth of an aneurysm is a manifestation of the law of Laplace, describing the relationship between tension T, stretching the blood vessel wall (the ratio of force to the area of longitudinal section of the vessel wall), its radius R, excess pressure P inside the vessel (transmural pressure), and its wall thickness a (see Figure 2.6(a)):
zyxwvu
T=PR/a
(2.5)
Another statement of the law of Laplace is used more often, where the left-hand part involves the product Ta, which is numerically equal to the force stretching the vessel wall and applied to its unit length. In such cases, assuming Ta = T', we have the following form of the law of Laplace:
46
zyxwvuts Chapter 2. Heart Pulse
2R
l I 1
zyxwvu
I I I I I I
E ~
I
o
BI /
I
rr"-
I
CD
I
T ' = PR
I
radius, R
(b)
zyxwvuts
F I G U R E 2 . 6 . Equilibrium for normal blood vessel wall under elastic tension: (a) the forces that are in equilibrium at the blood vessel wall (shown in cross section); (b) estimation of change in vessel radius occurring due to change in blood pressure.
T' -
PR
(2.6)
For equilibrium, then, the transmural pressure must always equal the circumferential tension divided by the radius. This means that the
Equilibrium of the Blood Vessel Wall: Aneurysm
zyxw 47
circumferential tension in the blood vessel wall has a sort of mechanical advantage in opposing the transmural pressure. It follows from Eq. (2.5) that, with P increasing, T should grow, too, which causes the vessel wall to stretch and its radius R to become larger. However, since the aorta wall volume can be considered a constant, the aorta radius increase should be accompanied by the thinning of its wall. Therefore, with P increasing, ratio R/a should grow as well, causing still greater T, and so on. Thus, any increase of arterial pressure would seem to result in an avalanche-like growth of R and decrease of a, leading to formation and blowout of an aneurysm. Then why does this actually occur in very rare cases and, as a rule, at a middle age? The aorta of a man has an inside diameter of about 2.5 cm and the wall thickness of 2 mm. The wall consists of cells containing two basic types of elastic materials, elastin and collagen. In an unstrained vessel wall, the collagen fibers are not straightened in full. So, the elasticity of an aorta wall under small deformations is determined by the easily stretched elastin. Under large deformations, the mechanical properties of an aorta wall are determined by collagen, which exhibits a much higher rigidity than elastin. Therefore, the dependence of tension T', which stretches aorta walls, on its radius displays a noticeable inflection and can be approximated by the segments of two straight lines with slopes that correspond to elasticity of elastin and collagen, respectively (Figure 2.6(b)). Let's examine the stability of the equilibrium of a vessel under the transmural pressure. The curved line in Figure 2.6(b) represents the relation between elastic tension and stretch. For equilibrium we must have the law of Laplace (2.6), which is represented by a straight line through the origin, the slope of which (tangent of the angle) is equal to the transmural pressure, P. The point A, where the Laplacian line and the curve intersect, represents the point of equilibrium. If the pressure were increased, a Laplacian line of increased slope would intersect the curve at B, indicating the increased radius at the increased transmural pressure. The equilibrium under transmural pressure and elastic tension is completely stable if the pressure changes in the indicated range. However, it must be recognized that if the transmural pressure is great enough, equilibrium may not be possible. In a certain case, as depicted in Figure 2.6(b) the curve of tension versus radius for arteries does not continue to increase in slope, but becomes a straight line. If the Laplacian line has a
zyxwv
48
Chapter 2. Heart Pulse
slope great enough to be parallel to this final slope of the elastic line (see a dotted line in Figure 2.6(b)), no intersection is possible. The vessel radius will increase until the vessel bursts. A similar process occurs under the blowout of aneurysm. The cause of the appearance and blowout of an aneurysm lies not only in the increased amplitude of arterial pressure but also in changes of mechanical properties of the arterial wall. The properties of collagen change in the elderly. It becomes less rigid, so that the aorta wall becomes easily stretched. In young people, the slope of the collagen part of the tension-radius curve corresponds to transmural pressure of about 130 kPa (1000 mm Hg), which is 6-8 times their actual arterial pressure. In middle-aged people, the rigidity of an aorta wall can decrease almost fivefold, and the arterial pressure can be as high as 26kPa (200mm Hg). This increases the probability of the emergence and the blowout of the aneurysm.
Murray's Law It is believed that biological form is regulated by a set of physiological principles that optimize function. Therefore, to operate efficiently, the mammalian blood circulation must obviously comply with a number of physical design principles. One of the principles described earlier calls for the minimization of a pulse wave reflection and the observance of Eq. (2.4) at sites of vessel branching. However, as follows from Table 2.1, Eq. (2.4) does not hold for branching of fine vessels, and the total cross-section area of capillaries is almost 1000 times the aorta cross-section area. This can be explained by the fact that the pulse wave amplitude decreases as the wave propagates from the heart to periphery, and so the blood motion through capillaries is practically uniform. This is why there is no need to observe Eq. (2.4) in the capillary part of the blood bed. There are, however, other principles, compliance with which helps to minimize expenses of energy for blood circulation. Murray (1926) also hypothesized that the design of the vascular system is such that the operating costs of the circulatory system are minimized. The operating costs consist of the cardiac work incurred in generating the pressure that drives the flow of blood and the metabolic work needed to make and maintain the blood.
zy
49
Murray's Law
Table 2.1 Arterial circulatory system of humans. For all four vessel types, the SUM (/'2), which should be constant by anti-reflection law, has been calculated (see Eq.z 2.4). Values for SUM (r 3) should be constant by Murray's law. Values for SUM (r 4) are given for comparison. Modified from LaBarbera (1990). (Reproduced by copyright permission of Science.) Vessel
Average Number SUM (r 2) SUM (r 3) SUM (r 4) radius, of vessels "no reflection" Murray's law cm law
Aorta Arteries Arterioles Capillaries
1.25 0.2 0.003 0.0004
1 1.6 159 6.4 1.4 • 107 127.4 3.9 x 109 1432
1.95 1.27 0.38 0.86
2.44 0.25 0.001 0.0005
zy
According to Murray's law, the total power required to sustain a regulated flow of blood through a segment of a blood vessel is assumed to be e -- ef + em
(2.7)
zyxwvutsr
where Pf is the power required to drive the flow of blood, and Pm is the metabolic power required to maintain the blood supply. For Hagen-Poiseuille flow, the power needed to overcome the viscous drag on the blood flow through the vascular segment of radius R, and length L is
Pf-
(811Q2L)/(rcR 4)
(2.8)
The power required for maintaining the blood supply is assumed to be proportionate to the blood volume, giving (2.9)
Pm - ~
where ~ is a metabolic constant for blood. We seek the optimal vessel geometry for given mean pressure and flow. Hence, after substitution of (2.8) and (2.9) into (2.7), the minimization conditions
aP/aR - 0
and
a2p/aR 2 >0
50 give
zy zyxwvutsr Chapter 2. Heart Pulse
Q - R3(o~/la)l/zrc/4
(2.10)
Proceeding from similar considerations, Murray concluded that in an optimal vessel system, volume flow is proportionate to a vessel diameter, cubed. Assuming that total volume flow doesn't change at any branch point, Murray derived the following relation. Murray's law: In an optimally designed system involving bulk laminar flow of a Newtonian fluid through pipes, at any branch point the radius of the parent vessel (Ro) cubed will equal the sum of the cubes of the radii of the daughter vessels (RI~ R2,R3,... ,Rn): R3 - R~ + R~ + . . . + R3n
(2.11)
One of the implications of Murray's law is that in the optimal circulation system the shear stress at the vessel wall, rw, is uniform throughout the system. Indeed, following from Eq. (2.10), r w -- 41,Q/(rcR 3) - (~it)'/2
(2.12)
As follows from Table 2.1, the variation of a radius of vessels along the blood bed is best described in terms of Murray's law, though even this law seems to be imperfect (cf. 1.95 for aorta with 0.38 for arterioles). Therefore, new attempts have been made to find a more adequate law to describe the branching of blood system vessels (for example see, Taber, 1998).
Blood Circulation in Giraffe and Space Medicine Who would not dream about flying into space and seeing the earth from the outside? Unfortunately, this dream will come true for only a few of us, so difficult and still dangerous is the job of an astronaut. Thousands, even tens of thousands of people get the spaceship to flight and solve the flight-related problems. A significant part of such problems pertains to a new field in biology called space biology. The first thing an astronaut faces at take-off is the acceleration, when the
Blood Circulation in Giraffe and Space Medicine
zyxw 51
spaceship rapidly picks up speed. In the course of launching the spaceship into orbit as the earth's artificial satellite, for almost five minutes an astronaut is subjected to acceleration, its magnitude varying between g and 7g. In other words, the astronaut's weight during the ship's blast-off may grow sevenfold. Accelerations also affect an astronaut as the spaceship enters the dense layers of the atmosphere when returning to the earth. Naturally, the increase in the astronaut's weight hinders his or her movements. Just try and imagine how difficult it would be to raise a sevenfold heavier hand to operate a toggle-switch on the control panel. Therefore, at times of overload (during the blast-off and deceleration), most operations related to the control of the ship should be automated. However, the difficulty of performing various movements due to the increased astronaut's weight is only one aspect of the effect of accelerations in a space flight, comparatively easy to bear. A greater danger lies in that accelerations also result in displacements of soft tissues and some internal organs along the direction of inertial forces. The most mobile part of an organism is, obviously, the blood. Therefore, under exposure to accelerations, the most significant changes arise in the circulatory system. If the acceleration is directed from pelvis to head, the effect of the inertial forces brings about the deflux of blood from the vessels of the head and its afflux to organs of the torso's lower part. This may result in vision disturbances and even fainting. If the action of acceleration in that direction lasts for a minute, its maximum value should not exceed 3g. Were the blood vessel walls absolutely rigid, the effect of inertial forces would fail to cause the redistribution of blood in an organism. All effects of acceleration in a circulatory system are due to the fact that blood vessel walls are highly distensible; owing to this distensibility, the change of blood pressure can alter the volume of blood vessels and of the blood they contain. The pressure of water in a vessel within the earth's gravity field increases with depth, so that 10cm submergence corresponds to lkPa pressure growth. If a vessel moves with acceleration ng, the water pressure will be diminishing in the direction of this acceleration vector by n kPa every 10 cm. Arterial blood pressure of a healthy man at the heart level is 16-18 kPa. In the sitting position, the head is approximately 40 cm above the heart level, so in the absence of accelerations the blood pressure in the large arteries of the head is equal to 12-14 kPa, which is quite enough for distension of the arteries.
zyxwv
52
Chapter 2. Heart Pulse
During the motion with acceleration 3g in the direction from pelvis to head, the arterial pressure in the vessels of a head diminishes by another 12 kPa, and becomes practically equal to the atmospheric pressure. Blood vessels collapse, the blood flow through them reduces sharply. Therefore, under such accelerations, the brain cells begin to suffer from the lack of oxygen, which brings about the loss of consciousness. For the same reasons, the pressure in the vessels of lower extremities under upward accelerations grows, and may reach 75 kPa at 3g. A more than fourfold increase of the arterial pressure brings about the excessive expansion of the vessels. As a result, the volume of blood in lower parts of the body increases and in upper parts diminishes. Besides, the vessels of the lower part of the body under the action of enormous pressure start leaking water through their walls into surrounding tissues. This leads to swelling of legs, called edema. How is normal blood circulation in an astronaut and a jet plane pilot to be ensured under the action of accelerations? The simplest solution is to position them so that their dimensions along the direction of acceleration vector were minimal. Then the arterial pressure in different parts of the body would vary insignificantly and no redistribution of blood would occur. This is why astronauts blast off and land in a reclining position. Interestingly, the same conclusion (to fly "lying sideways") was arrived at by the characters of Jules Verne's novel From the Earth to the Moon, written in 1870. Apparently, this novel by the great French science-fiction writer can claim priority in touching upon the main problems of space medicine. But what should the pilots of jet airplanes do? When executing a sharp maneuver, they cannot be in a lying position, as they have to control the craft at that very time. What if a pilot is dressed in a tight-fitting suit with water placed between its inside and outside layers? Then, under accelerations, the water pressure in any section of such a suit would change by the same value as the pressure in nearby blood vessels. Therefore, despite the pressure inside the vessel still growing, the latter would be unable to expand. No redistribution of blood would ensue. Such a suit became known as a g-suit and is successfully employed in astronautics and supersonic aviation. The majority of animals inhabiting the Earth are horizontal--the brain and the heart, the two most important organs, are located inside their bodies at the same level. This is very convenient. No additional effort is required by the heart to supply the brain with blood.
zy
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How Blood Pressure and Blood Flow are Measured
zy zyxw 53
Man cannot be termed as a horizontal animal, which is why he has relatively high arterial pressure. The hypertensives of the same kind include some birds (a rooster, for instance) and, of course, a giraffe. The heart of typical horizontal animals is unable to maintain the blood supply of the brain in an unnatural posture. For example, were a rabbit or a snake put in vertical position, they would very soon lose consciousness because of brain anemia. It turned out that an analog of a g-suit can be found in a giraffe. Of course, this does not imply that a giraffe is an alien from space. The necessity to wear such a suit on earth is explicable by an extraordinary great height of the animal: it may reach 5.5 m. The giraffe's heart is at a height of about 2.5 m, so the blood vessels of legs should experience a colossal pressure of all this column of liquid. What is it that saves a giraffe's legs from developing edema? Between the vessels of a giraffe's legs and its dense skin is a lot of intercellular liquid, which saves the vessels from excessive expansion in much the same way as the water in a pilot's g-suit. But how can giraffe's blood flow to the level of its brain, 3 m higher than his heart? If a giraffe had the heart blood pressure comparable to that of humans, then at the level of a head it would be lower than atmospheric, so that blood would not be able to pass through the brain. It is unsurprising, therefore, that a giraffe is a hypertensive. Its arterial pressure at the level of the heart may be as high as 50 kPa. This is the price a giraffe has to pay for its great height. The present day's fashion makes young people wear an analog of a gsuit m tight jeans. Doctors maintain that tight-fitting pants can help victims of severe injuries below the belt avoid a sudden drop of arterial pressure, typical in blood loss.
How Blood Pressure and Blood Flow are Measured One of the main indicators of the functioning of the heart is the pressure with which it delivers blood into vessels. In 1733, the Reverend Stephen Hales (1677-1761), a conventional vicar of Teddington, reported on his
54
Chapter 2. Heart Pulse
amazing direct measurement of blood pressure in a variety of animals, including horses. Of interest are the circumstances that brought Hales to the discovery of arterial pressure. Before taking up the research on the forces setting the blood of animals in motion, he had devoted several years to studying plants. In particular, he was interested in what makes the sap rise from the roots to the leaves of a tree. The results of his studies can be found in his book Vegetable Staticks published in 1727. Proceeding from the assumption that vegetable sap in a tree has the same role as blood in an animal, Hales undertook the investigation of blood circulation. Using a flexible tube, he connected the femoral artery of a horse to a long upright brass pipe with its top end remaining open. As soon as the clamp on the connecting tube was removed, the blood rushed from the artery into the brass pipe and started filling it until it rose to a level of about 2 m. The pressure of the blood column in the brass pipe was balanced by the arterial pressure (approximately 20 kPa). The blood level in the brass pipe was not constant m i t oscillated at the frequency of heart contractions between the maximal (systolic) and minimal (diastolic) values. Systolic pressure corresponded to the contraction of heart, and diastolic pressure corresponded to its relaxed state. He described this in the second volume of his works Statical Essays: Containing Haemastaticks (1733). Hales, however, was interested not only in the motion of liquids, but also in that of the air. And here, too, his ideas were translated into practice. To fight stuffiness in closed rooms, he was the first to suggest installation of windmill-like fans. The technique for measuring arterial pressure, proposed by Hales, was associated with considerable loss of blood and even the risk for a patient. For this reason, the technique can be used to measure arterial pressure, perhaps, in experiments on animals only. An aspiration to develop a technique for measuring arterial pressure that would be fit for a human caused the Italian physician Scipione Riva-Rocci (1863-1937), in 1896, to invent the instrument still in use now (Figure 2.7). Typically, the instrument is employed to measure blood pressure in an artery of an arm. Since an artery in a lowered arm is at the level of the heart, the blood pressure in the artery coincides with that in the part of aorta, nearest to the heart. The Riva-Rocci technique is based on measurement of external pressure required for pinching an artery. To this end, a hollow rubber cuff is placed on a patient's arm and, with the help of a pump, the pressure in it is raised
zy
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How Blood Pressure and Blood Flow are Measured
55
zyxwvuts
F I G U R E 2.7. Riva-Rocci-Korotkoff technique for measuring arterial pressure in men: (1) cuff; (2) rubber bulb with a valve for pumping air; (3) gauge for measuring air pressure; (4) phonendoscope for listening to Korotkoff's tones.
until the pulse in an artery of a forearm (brachial artery) disappears. The air pressure in the cuff at the moment when the pulse waves in the forearm artery disappear (when the blood flow in it ceases) should equal systolic blood pressure. In 1905, Russian physician N. S. Korotkoff modified the Riva-Rocci technique so that diastolic blood pressure could be measured as well. He suggested listening to the pulse waves in a forearm using a phonendoscope (the instrument comprises a sensitive membrane and two flexible tubes to take the sound vibrations to the eardrums). If the air pressure in the cuff is raised above the systolic one and then lowered slowly with the help of a special valve, distinctive sounds appear at the pressure equal to the systolic value. The origin of the sounds, known as Korotkoff's tones, is related to a complex character of pulse wave propagation along a partially pinched artery. When the pressure in the cuff becomes smaller than the diastolic one, the artery starts passing blood unimpeded and Korotkoff's tones disappear. Therefore, the pressure in the cuff, corresponding to disappearance of Korotkoff's tones, is recognized as the diastolic one.
56
Chapter 2. Heart Pulse
To get a full picture of the functioning of the cardiovascular system, it often does not suffice to measure the pulse rate and the arterial pressure. The unhealthy condition of some organ may be related to the diminished blood flow through the artery supplying it with blood. In these cases, to make a correct diagnosis, it is necessary to measure the velocity of blood flow through the artery (i.e., the volume of blood flowing through it in a unit of time). Among the first to study the velocity of blood motion along vessels was the French physician and physicist Jean L. M. Poiseuille (1799-1869). Interestingly, the law that is named after him and that relates the velocity of the motion of a liquid through a capillary to the radius, to the length of the capillary and to a pressure differential, was the generalization of experiments performed by Poiseuille on the blood vessels of animals. However, using Poiseuille's law to measure blood flow in the arteries of man is practically impossible, since this presupposes knowing the inside diameter of an artery, values of blood pressure at two points of it, and blood viscosity. Obviously, acquiring these data makes the technique rather "bloody" and often merely unrealistic. Presently the velocity of blood flow through vessels is normally determined with the help of the instruments of two types: electromagnetic flowmeters and devices using the indicator-dilution method. The electromagnetic flowmeter is based on the principle that when a conductor moves at right angles to the lines of force of a magnetic field, an electrical potential is induced. In this application of Faraday's law, the conductor is a stream of blood passing between the poles of a magnet. The induced current is led off by electrodes placed across the conduit of the stream. The current is proportionate to the velocity of the stream and its polarity is determined by the direction of the stream. It is noteworthy that one of the creators of the theory of electromagnetic induction, Faraday, seeking to verify the validity of the law of electromagnetic induction for conducting liquids, wanted to measure the difference of potentials between opposite banks of the river Thames, which arises as its waters flow in the earth's magnetic field. The application of this principle to blood flow was independently developed by A. Kolin in 1936 and E. Wetterer in 1937. Electromagnetic flowmeters represent a thin catheter with an outside diameter of 1-2 ram. This device can be introduced into many human arteries, with practically no
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How Blood Pressure and Blood Flow are Measured
zyxw 57
change in the velocity of a blood flow in them. As a rule, the value of magnetic flux density inside the flowmeters is 1 0 - 3 T, and so the recorded electromotive force at normal blood flow speeds rarely exceeds 1 0 - s V. Nonetheless, despite such a small magnitude of the signal at the pick-up output, the electromagnetic technique has found wide use in clinical and laboratory studies. The indicator-dilution method for the measurement of blood flow and volume arose from an almost two-century-old technique proposed by E. Hering in 1827, where potassium ferrocyanide was injected intravenously and the blood was collected at timed intervals from the corresponding contralateral vein. Hering tested for ferrocyanide by adding ferric chloride to serum. The first sample giving the Prussian blue reaction was, therefore, blood which had made one complete circuit from vein to heart, to pulmonary bed, to heart, to artery, to vein. The time at which this sample of blood was obtained (with a starting point set at the moment of intravenous injection) was called the circulation time. The indicator-dilution method, further developed by G. N. Stewart in 1921, made it possible to determine not only circulation time but also the bulk velocity of blood flow, provided one knows the amount of indicator (dye, or other agent) injected into the blood and its concentration at a certain point. In most cases, indicators are various dyes that are harmless to organisms and noticeably different in color from blood. In such cases the indicator concentration in blood is established by photometry, whereby the tint of a vessel is measured in transmission. Sometimes the cooled physiological solution is used as an indicator. The concentration of such an indicator can be estimated by measuring the temperature of blood in the vessel. The principle by which the injection of the indicator leads to a measure of flow is simple (Zierler, 1958). Over the years, two forms of injections have been used: in a sudden-injection, the indicator is injected very rapidly into the blood stream; in a constant-injection, the indicator is injected continuously at a constant rate. Consider first the case of the constant-injection (Figure 2.8). Inject the indicator at a constant rate, I, into an organ with a fixed but unknown volume, V, available for blood perfusion. Blood flows through an organ at a constant but unknown rate F. After an equilibration period (see the shaded area in Figure 2.8(a)), the rate at which the indicator leaves the system will exactly equal the rate at which it is introduced into the organ. The rate at
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58
Chapter 2. Heart Pulse
F I 6 U R E 2 . 8 . Principle of measurement of blood flow by indicator-dilution method. Left: schematic presentation of organ (or body part) through which blood flows at constant rate; indicator is injected into artery, which supplies the organ with blood. Right: concentration of indicator at organ outflow as a function of time during constant-injection, (a),or sudden-injection, (b). Arrows indicate the beginning and end of the indicator injection.
zyxw
which it leaves the organ is a product of the measurable concentration of the indicator at the outflow from the organ and the unknown flow of blood, or
l=C,,,a,,xF
zy
(2.13)
where Cm,,x is the concentration of indicator at outflow. The relationship (2.13) makes it possible to compute F, provided / and Cm~x are known. It should be noted that the indicator-dilution method in described modification yields true values for the blood flow velocity in that case only when the indicator, after leaving a given section of a vessel or organ along with blood, is later withdrawn from the blood (e.g., by kidneys). Otherwise, the concentration of the indicator in blood would gradually grow and the computation of F according to Eq. (2.13) would result in too high values. In the case of sudden-injection, a known amount of indicator is introduced into a blood vessel during a short time (about 1second). In
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How Blood Pressure and Blood Flow are Measured
zyxw zy 59
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this case, the concentration c(t) of the indicator at the outflow from the organ will fail to be constant, but will vary in the manner similar to that shown in Figure 2.8(b). If velocity F of blood flow through an organ is assumed as constant, the amount of indicator leaving the organ during the time interval dt will equal c(t)Fdt. The total amount of indicator that has flown through the organ will equal Ffc (t)dt. If it is known and equals q, the equation q -- Ffc (t)dt yields
F - q/f c (t)dt
(2.14)
To find the volume, V, of an organ available for blood perfusion, first consider particles of blood entering the organ. The particles entering the organ at the same time require varying amounts of time to reach its outflow, the time required for any particle depending on the path taken and the velocity with which the particle travels. The blood (and indicator), therefore, does not have a single traversal time from inflow to outflow from the organ, but rather a distribution of traversal times. However, it is easy to come to the conclusion that
V=Fxt m
(2.15)
where tm is the mean traversal (or circulation) time which equaled
(F/q). f tc(t)dt. The earliest technique for studying the blood flow velocity, still in use at present, is the one suggested by the German physiologist Adolph Fick in 1870 when he was just 26 years old. To establish the amount of blood, F, ejected by the heart in a unit of time (i.e., the velocity blood flow throughout the organism), he measured the concentration of oxygen in arterial (A) and venous (V) blood and also the amount of oxygen (O) consumed by an organism in a unit of time. The amount of oxygen received by an organism from a unit volume of arterial blood is A-V. If the organism passes F blood volumes in a unit of time, the amount of oxygen consumed by organism is F ( A - V). On the other hand, this quantity (O) can be estimated by measuring the concentration of oxygen in an inhaled and an exhaled air. Since 0 = F ( A - V), we have
Chapter 2. Heart Pulse
60 F = O/(A - V)
(2.16)
Again it should be noted, though, that the Fick technique is applicable to investigation of the velocity of blood flow through the heart only (total blood flow). Widely used nowadays is the ultrasonic technique for measuring linear velocity of blood motion. The technique employs the well-known Doppler effect according to which the frequency of perceived sound vibrations is dependent on the velocity of the sound source motion relative to the sound receiver. Short pulses of ultrasound waves are transmitted diagonally across the blood vessel flow profile from one crystal and received by the other. Immediately, a second pulse originates in the second crystal and is received by the first. The average velocity of flow is derived from the time difference of sound transmission up and downstream. The frequency of the applied ultrasound is usually in the range between 1 and 10MHz. The blood particles that scatter ultrasound and, therefore, act as its secondary moving sources are erythrocytes with sizes of about 5/~m. Besides, some ultrasonic flowmeters measure the difference between the frequencies of transmitted ultrasound and that scattered by blood, which also makes it possible to compute the velocity of blood motion, given the position of a vessel relative to the pick-up and the speed of ultrasound in the medium. Despite an apparent ease of measuring the velocity of blood motion with the help of Doppler's principle, its application calls for use of special electronic equipment capable of detecting frequency changes about 0.001% of the transmitted one. Note that the ultrasonic technique allows for finding just the linear velocity of blood motion, rather than the velocity of blood flow (see earlier). The latter, obviously, can be computed, if we multiply the velocity of blood motion by the cross-section area of a vessel. Unfortunately, in most cases the cross-section area of a blood vessel is difficult to evaluate with sufficient accuracy. In these cases the ultrasonic technique can provide us with the data only on the relative changes in the velocity of blood flow, with the crosssection area of a vessel assumed unchanged.
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Blood Color and the Law of the Conservation of Energy
61
Blood Color and the Law of the Conservation of Energy
Well now, let us relax again before turning to the next chapter. The law of the conservation of energy in its clearest form was first stated in 1842 by the German physician and physicist Julius R. von Mayer (1814-78). This physical law was discovered under highly unusual circumstances. In 1840, Mayer went out to sea as a surgeon on board a Dutch ship to the faraway island of Java. At those times, the most widely used method of therapy was bloodletting, and it was common for a physician to see a patient's venous blood. And so, as they were approaching warm equatorial latitudes, Mayer noticed that the color of the venous blood of seamen became redder than it was in Europe. This signified that more oxygen is retained in human venous blood at southern latitudes than at northern ones. It is obvious that the oxygen concentration in arterial blood is the same for different latitudes and depends only on its concentration in the atmosphere. This led Mayer to conclude that in cold climate men consumed more oxygen. He further deduced that maintaining the same body temperature in cold weather required a greater oxidation of food products. However, Mayer realized that the energy released in combustion of food products was spent not only on maintaining constant body temperature in a man but also on his performing mechanical work. This meant that certain relationships should hold between the amount of heat generated in an organism and the mechanical work a man performs during a given interval of time. So Mayer concluded that a certain amount of heat should be in correspondence with a certain value of mechanical work delivered. The idea of equivalence of heat and work attracted Mayer at once. Afterwards, Mayer's life went awry. There was a lot of argument around Mayer's priority in the discovery of the law of conservation of energy. Both this and troubles at home took their toll on the scientist's mind. In 1851, he was committed to a mental institution. Though after some time he was discharged, his contemporaries noted that Mayer's mind never recovered.
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Crocodile Tears and Other Liquids
Amazing as it may seem, we are all more than half water. As Table 3.1 shows, the water content in every organ and tissue (except for fat and bones) lies in a range between 60 and 85%. Normally, the ingress of water into an organism and its loss are balanced. In conditions of moderate climate, a person consumes 2.5 L of water a day on average; the corresponding water balance is described in Table 3.2. Thus, the daily water cycle of an adult is on the average about 3 - 4 % of body mass. The minimal daily water demand of an adult is considered to be 1.5 L, 0.6 L of it necessary for removal of waste products by kidneys, with the remaining 0.9 L evaporating from the skin surface. The greater part of substances removed by kidneys is comprised by urea (30 g, or about 0.5 M a day) and sodium chloride (10 g, or about 0.2 M a day). Thereby, the maximal concentration of osmotically active substances in urine amounts to 1200-1400mOsm/kg H 2 0 , which determines the minimal volume of liquid discharged with urine. The reduction of ingress of water into an organism (dehydration) is fraught with serious consequences. Some of them are related to the fact that
63
z
zy
64
Chapter 3. Crocodile Tears and O t h e r Liquids
Table 3.1. Water content values for various organs and tissues. 1 (Reproduced by copyright permission of Academic Press.) Tissue
Water Content, %
Skin Muscle Bone Brain Liver Lung Kidney Spleen Bone Marrow Fat
60-76 73-78 44-55 68-85 73-77 80-83 78-79 76-81 8-16 5-15
1Data from Pethig (1991).
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the blood in this case becomes more concentrated and viscous, consequently losing its ability to flow along the finest capillaries of most organs, so that such organs begin to die off. In cases when the amount of water in an organism diminishes by a third, death ensues. It is noteworthy that cases of death caused by dehydration were observed in shipwrecked people who tried to quench their thirst with seawater, the osmolarity of which is about 900 mOsm/kg H20. The cause of dehydration is the fact that, in order to remove salts contained in seawater, the organism
Table 3.2. Daily water balance of adult human1. (Reproduced by copyright permission of Mosby Publisher.) Water intake Drinking Food
mL/day Water losses
1200 900 M e t a b o l i c processes 2 300 Total 2400
mL/day
Urine 1400 Lungs and skin 900 Feces 100 Total 2400
1Data from Muntwyler (1968). 2Oxidation of 1 g of hydrocarbons, fats, and proteins yields 0.6, 1.1 and 0.4ml of water, respectively.
Water in Us
65
is forced to use its own water, with the consumption of 1 L of seawater accompanied by the formation of at least 1.6 L of urine. But then, how do sea birds quench their thirst? In 1939, the well-known Norwegian physiologist Knut Schmidt-Nielsen decided to find the answer to this question. He caught several arctic gulls, placed them in cages, and started feeding them with fresh sea fishes. Under such a diet, the gulls showed no signs of thirst and Schmidt-Nielsen inferred that the birds received all required water with the caught fish, in which the concentration of salts was much lower than in seawater. Well then, what if the fish swam to the sea bottom as is the case during a sea storm? Then, obviously, the gulls have no choice but to drink seawater. To learn how gulls discharge salts out of an organism in that case, SchmidtNielsen started to force them to drink seawater, expecting to observe an abrupt increase in the concentration of salts in their urine. However, it turned out that such a salt diet, by all means, failed to produce an increase in the concentration of salts in the urine of gulls. Instead, they take to "weeping." Faced with the excess of salt, special glands near the beak squeeze out a liquid in which the concentration of salts can be several times higher than that in seawater. Apparently, the same happens with crocodiles, who often inhabit salty water, so that the "crocodile tears," which became a synonym of hypocritical compassion, could be another means of discharging excessive salts out of an organism. However, for obvious reasons, nobody ever studied crocodile tears in detail. Human tears also contain salts; however we are, of course, unable to "weep out" all the salts that enter our organism daily. That is why we can rely only upon the functioning of our kidneys.
Water in Us How can we find out how much water there is inside us? Usually the techniques based on the principle of indicator dilution are used for this purpose. It is evident that if a person's blood is injected with a harmless substance, which will freely (the same way as water) permeate the membranes of all cells of an organism, then after some time its concentration will become the same throughout all liquid phases of the organism. After that, the volume of the liquid phase of the human body can be determined by
z
66
Chapter 3. Crocodile Tears and Other Liquids
dividing the amount of injected indicator to its concentration in the organism. To establish the total volume of water in an organism, antipyrine, as well as heavy water (D20 or 3H20), is most often used as an indicator. In two hours' time, these substances become uniformly distributed among various liquids of the organism. During that time, however, a fraction of the injected substance is withdrawn from the blood bed and is concentrated in the bladder, which interferes with the evaluation of a true volume of liquid phase of an organism. Therefore, a mathematical model is needed to provide a qualitative approximation of the indicator dilution process. Let V be the volume of a liquid phase of organism; C(t) be the concentration of indicator in it; A C be the change of the concentration during the time period At and Vo be the volume rate of discharge of liquid together with the dissolved indicator through the kidneys. Then the law of conservation of mass (for indicator) yields
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zyx
V A C -- - C v o 9 At
(3.1)
By integrating Eq. (3.1), we get In C(t) -- In C(O) - t , ' o / V
(3.2)
where C(0) is the concentration of indicator immediately after its injection into an organism (assuming its penetration into all liquid media and its mixing occur instantaneously). It follows from Eq. (3.2) that the curve C(t) in semilog coordinates should have the form of a straight line intersecting the axis of ordinates at point C(0). Thus, if the experimental indicator dilution curve (i. e., the dependence of indicator concentration on time) is plotted in semilog coordinates and fit to the axis of ordinates (Figure 3.1), we can obtain the desired value C(0) required for computation of the volume of the liquid phase of an organism. The actual measured indicator concentration (solid line) in the left-hand part of the plot in Figure 3.1 is noticeably higher than its fit (dashed line). This is evidence that in reality the uniform distribution of the indicator fails to take place instantaneously, and that during all this time its concentration in blood somewhat exceeds the one in other liquid media of the organism. In adults, the mass of water contained in the organism and measured in
zyxwvutsr zyxwvuts 67
Water in Us
"5 ,- ~ .o_
1.o-I
0.9
0.a
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8.c_ ",.~ >
-'-'
._o
0.6
time, min 0
10 '
2' 0
30 '
4'o
50 '
60 '
F I G U R E 3 . 1 . Determination of the volume of liquid with the help of indicator dilution technique. Plotted is the variation of indicator concentration (C) in patient's blood plasma upon a single (as a single bolus) injection of indicator. (Modified from Pitts, 1974.)
the described manner on the average amounts to 60% of body mass for men and 50% for women, with a greater part of water being found in muscles (32% of body mass), skin (13%), and blood (7%). A similar method can be used to measure the volume of extracellular liquid in an organism: a person's blood is injected with indicators incapable of penetrating through cell membranes. Such indicators are typically various sugars, while inulin, which is removed from an organism very quickly, was selected by researchers as a standard substance to be used for determining the total extracellular space (see Figure 3.1). The mass of water in extracellular space found with the help of inulin (inulin space) on the average amounts to 16.5% of body mass. However, if we use a substance that is removed from the organism slowly (e.g., thiocyanate) as an indicator, and wait for a long enough time (from 5 to 10 hours), it will turn out that the true extracellular space may amount to 27% of body mass. The volume of water contained inside cells can obviously be found by subtracting the extracellular fraction from the total water contained in an organism. Therefore, the intracellular water is believed to amount to about 33% of a person's mass.
68
Chapter 3. Crocodile Tears and Other Liquids
Amazing Filter All the cells of our organism are surrounded by intercellular liquid on every side. A necessary condition of a cell functioning is the constancy of the volume and composition of the liquid. This statement was first advanced more than 100 years ago by the well-known French physiologist Claude Bernard (1813-1878). In what way is this constancy maintained? In principle, the amount of water in our organism and the composition of intercellular liquid are regulated by us subconsciously when, for instance, we appease the feeling of hunger or thirst, since we receive water and electrolytes mostly with eating and drinking. An exception is the so-called metabolic water forming in the oxidation of food products (see Table 3.2). The greater part of the excessive water and electrolytes is removed through the kidneys. Therefore, the base of maintaining the constancy of the volume and composition of liquids in an organism is the normal functioning of kidneys. A functional structure unit of a kidney, which is the site of urine formation, is the nephron (Figure 3.2). Each human kidney weighing about 150 g contains approximately one million nephrons.
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arterial blood venous b\~176
14
F I G U R E 3 . 2 . Schematic presentation of a nephron and its blood supply: 1, renal corpuscle; 2, renal tubule bent in the form of 3, Henle's loop.
Amazing Filter
69
A nephron is made up of two main parts: renal corpuscle and tubule (descending and ascending limb, marked 1 and 2, respectively, in Figure 3.2.) Blood, passing along capillaries situated in the corpuscle, filters through their walls and the resulting filtrate finds itself in a cavity opening into a tubule. This liquid, which is already free from molecules with molecular weight in excess of 80 kD, became known as primary urine. Its daily volume amounts to about 180 L; it differs in composition from blood plasma solely by the absence of high-molecular proteins. The source of energy for blood plasma filtration in a renal corpuscle is the work of the heart. The heart, when contracting, produces excess pressure (20-30 mm Hg) inside a corpuscle capillary, which is what forces some part of blood passing along the capillary to filtrate through its wall and form primary urine. In a renal tubule bent in the form of Henle's loop (marked 3 in Figure 3.2), concentration of primary urine takes place. As a result, 99% of water (178.5 L a day) returns back into the blood and mere 1.5 L is discharged in the form of urine. Here, the osmolarity of urine may be as high as four times that of blood plasma, which is typically in the range between 285 and 295mOsm/kg H20. Let's consider in greater detail the way the concentration of solution in Henle's loop occurs. The first model to explain the mechanism of the solution concentration in Henle's loop was proposed by Kuhn and Ryffel (1942) and elaborated later in the work of Hargitay and Kuhn (1951). Kuhn and his coworkers suggested that the Henle's loop provided a countercurrent system in which a concentration of solutes could be multiplied manifold. To model Henle's loop, they presented it as a tube divided with a semipermeable membrane (M) into two limbs (left, L, and right, R) of the same size (Figure 3.3). The loop limbs are interconnected via a narrow capillary tube (C), along which the liquid flows from the left limb into the right one under the action of pressure. First, let the capillary connecting the loop limbs be closed and both limbs be filled with liquid of the same composition (Figure 3.3(a)). Naturally, in this case there will be no movement of liquid along the loop. However, if hydrostatic pressure is applied to limb L, the water (for which the membrane is permeable) starts moving from the left limb into the right one. As a result, the concentration of substances in the left limb will grow, and in the right, decrease.
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Chapter 3. Crocodile Tears and O t h e r Liquids
70
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F I G U R E 3.3. Illustration of countercurrent mechanism of urine concentration in Henle's loop.
Still, as soon as the concentration of substances in the left limb of the loop starts growing, a reverse flow of water (from right to left) arises, the flow caused by the osmotic pressure gradient, l It can be shown that the gradient of osmotic pressure A~ is computed according to formula
- RT(C
- C.)
(3.3)
where R is the gas constant, T is the absolute temperature, and CL and CR are the concentrations of solutes in left and right limbs of the loop, respectively. It is obvious that when the left-to-right water flow, caused by the hydrostatic pressure gradient, becomes equal to the osmotic flow from right to left, an equilibrium will be attained (see Figure 3.3(b)). It will occur when the osmotic pressure gradient becomes equal to the hydrostatic pressure Osmos is the term used to refer to the transport of solvent (in this case, water) through a semipermeable membrane separating two solutions with different concentrations. Here, the solvent molecules pass through the membrane, impermeable for solutes, into a more concentrated solution. The process runs until the concentrations are balanced.
Amazing Filter
zy zyxwvu 71
applied to the left limb of the loop; the corresponding difference of concentrations can be found with the use of Eq. (3.3). Now, let us open capillary (C) connecting the loop limbs. Since the capillary is very narrow, the hydrostatic pressure gradient between the limbs can be considered to remain unchanged. At the same time, immediately after opening the capillary (at first, in the lower part of R and later in the upper one, too) concentrated liquid will appear (see Figure 3.3(c)). This means that the equilibrium between L and R is disturbed (the gradient osmotic pressure has decreased) and the water ingress from left to right will recommence. As a result, the concentration of substances in the liquid of the left limb near the capillary is growing. Thus, the countercurrent system of liquids exchanged through a semipermeable membrane leads to the concentration of solution near the turning point (Figure 3.3(d)). It is obvious that in the state of equilibrium the concentration of a solution that outflows from the loop (see Figure 3.3(d)) is the same as that of the one that enters. Consequently, the capability of a countercurrent loop for concentration is not used in this case. To remove the concentrated solution from Henle's loop, nature provided for the third (T) limb. In accordance with the model of Kuhn and his coworkers, the limb is separated from R by a semipermeable membrane and connected to R by a small opening (Figure 3.3(e)). Since the opening is very small, only a small fraction (about 1%) of liquid flows out of R into limb T, and for this reason, the motion of the liquid along the loop and the concentration gradient are not disturbed. At the same time, the liquid, which moves slowly top-down along limb T (the diameter of the limb is the same and the liquid flow rate is about 1%), attains osmotic equilibrium through the semipermeable membrane and exits the three-limb Henle's loop with a very high concentration of substances, which equals the one at the junction of R and L. Let us try to estimate the capability of Henle's loop for concentration. Divide each loop limb vertically into N segments: the first one at the top and the Nth one at the very bottom (Figure 3.4). Let the concentration in the left loop limb in kth segment at moment t be equal to Lk(t), and in a similar segment on the right, equal to Rk(t ). To simplify the computations, let us assume that the solution motion along the loop has an intermittent character. Thereby, the solution instantly moves over by the length of segment s, staying at rest afterwards for time interval s/v where v is the average linear velocity of the liquid motion along
72
FIGURE 3.4.
Chapter 3. Crocodile Tears and Other Liquids
Elements of Henle'sloopmodel.
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the loop. We shall consider the transport of water between the neighboring limb segments through a semipermeable membrane (fully permeable solely for water) to occur only upon completion of the next-in-turn step and to last for the time period equal to s/v. The process of solvent transport (in this case, water) through a membrane under the action of hydrostatic pressure gradient is referred to as ultrafiltration. Volume rate A V/At of ultrafiltration can be determined from the equation A V / A t -- kfA(p -+- Arc)
(3.4)
where k r is the filtration factor, A is the membrane area, p is the magnitude of hydrostatic pressure gradient, and Art is the osmotic pressure between these solutions, the pressure related to the concentrations of substances in them by Eq. (3.3). Let all loop segments be identical and have the shape of a cube with lateral face area A. Then, substituting At - s / v and assuming V = sA, we obtain A V / V = kf {p + RT(R k - Lk) }/v
(3.5)
z zyxw
Amazing Filter
73
Expression (3.5) enables us to compute the relative change of the water amount after a single ultrafiltration interval with duration s/v. Evidently, knowing this we are already able to evaluate the changes of concentrations in both adjoining segments after a single act of ultrafiltration: L k (after) = (1 + AV/V)L k (before) Rk (after) = ( 1 - AV/V)R k (before)
(3.6)
Well, we seem to have described the ultrafiltration in full, but the liquid also moves. Let us write down kinematic relationships. Let our unit of time (t) be s/v. In our model, the solution that has just entered the left kth segment is of the same osmotic concentration as the (k-1)th segment at the previous moment in time (similar dependencies are valid for the right limb segments). Therefore, kinematic relationships will have the form
Lk(t + 1) = Lk_ , (t) Rk(t + 1) = Rk+ I (t)
(3.7)
Primary urine with a constant osmotic concentration, a, keeps entering the first segment of the left part of the loop; hence, in computations using Eqs. (3.6) and ( 3 . 7 ) w e should let L 1 = Ll(before) = a. In addition, for computations using Eq. (3.7) we should, obviously, let L 0 = a. The liquid enters the lowest segment of the right limb of the loop immediately from the lower segment of the left limb, bypassing the capillary, its volume being negligible. Therefore, RN+ 1 in Eq. (3.7) should be assumed equal to L N. Simultaneous equations (3.5)-(3.7) describe the change of osmotic concentrations in transition from t to t + 1. To solve the equations, it is necessary to set initial conditions; that is, the values of variables at t = 0. Assume that at instant t = 0 the loop is filled with primary urine having osmotic concentration a, but there is no motion of the solution (hydrostatic pressure is not applied to the left limb). Then, evidently, we should let Lk(0 ) = Nk(0 )
=
a
(3.8)
74
C h a p t e r 3. C r o c o d i l e Tears and O t h e r Liquids
The set (3.5)-(3.7) with initial conditions (3.8) is solved rather easily with the use of PC. If we let N = 50, a = 3 0 0 m O s m / k g H 2 0 , p/RT = 100 mOsm/kg H 2 0 , kf = 2- 10-1~ p a - l s -1, v = 0.00004 m/s, RT--2.24kPa/mOsm/kg H 2 0 , it turns out that as time goes on, L N gradually attains a steady-state value that equals (in Osm/kg H20): t LN
10 0.38
20 0.43
50 0.53
100 0.65
200 0.83
500 1.16
1000 1.38
2000 1.44
5000 1.45
Of course, it is impossible to determine exactly the factors involved in this set of equations. Therefore, the computation results should be taken solely as an illustration of the physical process running in the countercurrent loop, with attention paid to basic patterns only. Figure 3.5 shows the values the solution concentration (C) takes on in different segments (k) of Henle's loop under such simulation. It follows from the data obtained in simulation that the countercurrent mechanism of concentration can increase the solution concentration at the turning point of the loop fivefold. Note that ultrafiltration by itself (without countercurrent)
N = 50
1.5
-4
1.0
o
20
0.:3
9
0
5
9
10
w
|
20
50
F I G U R E 3 . 5 . Dependence of solution osmolarity (C) on sequential number (k) of segment, evaluated for model in Figure 3.4. Plotted are the curves for Henle's loops of different lengths (N = 5, 10, 20, and 50).
zy zy
Cryobiology and Biological Antifreezes
zyxw 75
is able to increase the solution concentration by mere 50 mOsm/kg H 2 0 (by 17%). Our model allows for assessment of the dependence of the capability of the loop for concentration on its length (see curves in Figure 3.5 for N = 5, 10, 20, and 50). As we should expect, the longer the loop, the greater its capability for concentration. It is obvious that for mammals living near freshwater reservoirs, and sometimes right in them, water is no problem. There is small need for them to save water. For this reason, the amount of water in urine may be large and, hence, the concentration of substances in urine (osmolarity), low. On the contrary, for mammals living in deserts, far from water bodies, every drop of water counts. Therefore, removing waste products with urine, desert inhabitants must raise its osmolarity as high as possible. Indeed, Schmidt-Nielsen and O'Dell (1961) demonstrated that the osmolarity of urine in beavers amounts to less than 0.50sm/kg HzO , whereas in the desert rodent Psammomys it exceeds 4 0 s m / k g HzO. The difference in osmolarity of urine in these animals can be accounted for by the fact that Henle's loop in the desert rodent Psammomys is almost 10 times longer than that in beavers. Of course, during the past 40 years the model proposed by Kuhn and coworkers has many times come under criticism for oversimplification. Therefore it was followed by more involved models, which take into account recent experimental data (Stephenson, 1973; Layton, 1986; Weinstein, 1994). However, like in the model of Kuhn and coworkers, in all the new models, the crucial part still belongs to Henle's loops, which act as a countercurrent multiplier.
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Cryobiology and Biological Antifreezes Life is possible in a very narrow temperature range, from several degrees below freezing (0~ to 40-50~ Of course, it is the body temperature, not the temperature of the environment that matters here. Temperature fluctuations radically affect many physiological processes. Temperature reduction slows metabolism to such an extent that a 10 degree temperature decrease entails a 2-3 times decrease in the rate of physiological processes. The latter observation is used widely in a long-time storage of certain
76
Chapter 3. Crocodile Tears and Other Liquids
isolated organs and fluids of a man. For example, sperm tanks are stored in liquid nitrogen a t - 1 9 6 degrees C. And every year thousands of cancer patients receive transplants of their own frozen bone marrow, to replace the cells destroyed by radiation or chemotherapy. Having found themselves outside the range of temperatures compatible with active life, many animals are capable of surviving by passing into a state of torpor or hibernation. However, such resistance with respect to low temperatures is not exhibited by all organisms. Anyone who keeps tropical fish in indoor fish bowls knows, perhaps, that once the heating is disconnected, the first cool night will kill all the fish. It has been established that the cause of the death of a cell due to freezing is the formation of ice crystals inside a cell. The ice crystals destroy intracellular structures, and, as a consequence, the cell dies. Therefore, to save a cell from "crystal" death in low temperatures, the cell must be freed from the source of crystals m water - - replaced (at least partially) with another liquid. Glycerin has long been known to protect living organisms against damage in freezing. Hemolymph of insects contains glycerin in a high concentration (several tens of mM/l) and their survivability at low temperatures is attributed to this. Thus by the onset of winter, glycerin concentration in wasps increases several times, and in this period glycerin is responsible for about 3% of the total liquid content of the insect. As a result, the freezing point of hemolymph of wasps falls down to -17.5 degrees C. The same explanation apparently holds for the recent entomological discovery. In one of the Himalyan glaciers they found a mosquito-like insect who was fairly active at temperatures b e l o w - 1 6 degrees C. It has been proven that the ability to survive abrupt onset of cold by way of increasing the glycerin content in blood is typical not only of hibernating insects. Thus, common meat flies easily survive temperatures as low a s - 1 0 degrees C. However, they survive only under a relatively gradual onset of cold. Thus, whereas abrupt (several seconds long) freezing t o - 1 0 degrees C is lethal for all insects, practically all of them can survive gradual freezing (0~ for two hours, and then -10~ It turned out that the reason for such a fast adaptation of insects to the freezing temperatures is a threefold increase in glycerin concentration in their hemolymph. This, apparently, helps them survive during frosts in early spring and late fall.
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Cryobiology and Biological Antifreezes
zyxw 77
The feature of glycerin as a good cryoprotector finds wide use in biology and medicine. It is known that erythrocytes can be stored in the frozen state for many months without damage, provided they are immersed in glycerin. A similar method can be used to protect even entire animals against cryodamages. Thus in 1992, research workers from the cryogenic company BioTime in Berkeley, California, cool a baboon down to about 2 degrees C and preserve him in this state for 55 minutes using a patented cold-resistant substitute, similar to glycerin in its properties. After this, the monkey was refrozen without any apparent consequences. You can learn of other semifantastic experiments on freezing animals from the paper by J. Knight (1998). In contrast to mammals, ectothermic vertebrates (fish, snakes, frogs, turtles, lizards) that live in conditions of cold climate endure long cold winters, when their temperature may fall far below the freezing point of water. Nature employs at least two methods to protect these animals against death under such conditions: 1. Fish of subpolar seas synthesize antifreeze glycopeptides or antifreeze peptides (AFP) preventing ice crystal growth down t o - 2.2 degrees C or below, which is substantially lower than the temperature of iceladen seawater (DeVries,1988). 2. Other ectothermic vertebrates inhabiting the land have developed the ability to endure the freezing of extracellular fluids to such an extent that during wintering as much as 65% of their total body water is locked in ice (Storey and Storey, 1992). The fish swimming in cold subpolar waters (winter flounder, Alaskan plaice, and shorthorn sculpin) exhibit a unique capability not to freeze, remaining in the supercooled state down to temperature-2.2 degrees C. In comparison, most fish of tropical and midlatitudes freeze, with ice present, when cooled down to -0.8 degrees C. The comparison of the two figures would make some smile m a mere 1.4 degrees?! Yes, it is these one and a half degrees that help Antarctic fish survive. Indeed, at inlet McMurdo Sound (the part of the ocean nearest to the South Pole), for instance, the average annual temperature i s - 1 . 8 7 degrees C with variations f r o m - 1 . 4 t o - 2 . 1 5 degrees C. However, the mechanism used by winter flounder to avoid freezing when swimming among ice is different from that used by insects. Before we learn the secret of subpolar fish, let us see upon what the
78
Chapter 3. Crocodile Tears and Other Liquids
formation of ice crystals depends. It has been established that freezing points of most solutions depend on the amount of dissolved particles, rather than their nature. The presence of dissolved particles obviously diminishes the probability of formation of a nucleating center, since the number of collisions of water molecules with one another goes down. For instance, such is the action mechanism of salt solutions, still in use in many cities to fight icing. Glycerin, which precludes freezing of insects in a cold season, apparently acts in a similar way. Yet another, more refined action mechanism of antifreezes is possible, one that does not require their high (sometimes, molar) concentration. It turned out that some polypeptides and glycoproteins, whose molecules have the helical shape and consist of a multitude of repeating units, and whose molecular weight ranges between 3000 and 30,000 D, are capable of lowering the freezing point noticeably already in millimolar concentrations. And if these protein antifreezes are compared to NaCI, the former prove to be 300-500 times more efficient. What is the action mechanism of antifreeze peptides? Molecules of water in ice crystals form hexagonal lattice with oxygen atoms at vertices of hexagons. Therefore, under the ideal conditions the ice crystals are hexagonal pyramids. It was established (Knight et al., 1991) that numerous polar groups in molecules of antifreeze peptides, extracted from winter flounder and Alaskan plaice and capable of forming hydrogen bonds with water molecules, are located at the same distance from each other (16.7~) as the water molecules along one of their directions {0112} in pyramidal planes of ice. As a consequence, long molecules of antifreeze peptides can considerably slow down the crystal growth by binding to the fast-growing end-face. Antifreeze peptides are responsible for about 3.5% of mass of all liquids in a polar fish body. It is these antifreezes, acting jointly, that lower the freezing point by approximately 1.2 degrees C. Lowering it by still another degree is due to various ions and molecules (mostly NaCI)contained in liquids of Antarctic fish. The concentration of antifreeze peptides in liquids of warm-water fish is negligible. The study of the binding mechanisms of antifreeze peptides to ice surfaces potentially has numerous practical applications. For example, it is crucial in cryopreservation research since ice crystal growth can significantly damage cryopreserved biological material. Therefore, adding the antifreeze peptides
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Cryobiology and Biological Antifreezes
79
to a protectant solution could reduce damage due to ice crystal growth. Further practical applications include prevention of damage to agricultural crops by early frost (Kenward et al. 1993) and inhibition of ice crystal growth in foods stored at low temperatures (Feeney and Yeh, 1993). Extracellular liquid in animals and plants freezes earlier than does intracellular liquid. Under slow freezing of extracellular salt solution, water crystallizes, whereas salts accumulate between crystals, raising the osmotic concentration of the remaining extracellular solution. As a result, concentrated extracellular solution sucks the water out of cells, and they are dehydrated. The freezing point of intracellular solution lowers. Thus, if conditions are provided for prevailing formation of ice crystals in extracellular liquid, the cells proper can be saved from freezing. Ectothermic vertebrates wintering on land resort to this way of salvation. Experiments performed on wood frogs, R. Sylvatica (for review, see Storey and Storey, 1992), showed that the frogs can endure a decrease of body temperature down to -4 degrees C, lasting for several days, whereby the frogs consist of ice by more than a half of their body. Thereby, ice crystals appear only in extracellular liquids of frogs, rendering the freezing process reversible. Reptiles and amphibians have the ability to supercool (chill below the freezing point without freezing). Ice-nucleating proteins, appearing in blood immediately before wintering, initiate and control the formation of ice in extracellular fluids of freeze-tolerant animals. The action of frog icenucleating proteins results in a mean supercool point o f - 6 degrees C compared t o - 1 6 degrees C for human blood plasma. Amazingly, the addition of mere 0.5% vol/vol of cell-free frog blood raised the supercool point of human plasma t o - 7 degrees C, suggesting that frog ice-nucleating proteins might be used as effective agents in cryomedical systems. Note that in spring and summer reptiles and amphibians stop synthesizing the icenucleating proteins and lose this freeze-tolerant ability. However, it is not always the case that the presence of ice-nucleating proteins that facilitate the ice crystallization helps organisms survive under lowering of the temperature; sometimes it becomes the very cause of their death. Such is, for instance, the role of some kinds of proteins discovered on the outer membrane of bacteria Erwinia herbicola, Pseudomonas syringae, and others. These bacteria, which can usually be found on surfaces of plants in Europe, Asia and North America, belong to a harmful category, and are
80
zy zyx
Chapter 3. Crocodile Tears and Other Liquids
considered to cause the low cryoresistance of plants (Arny et al. 1976) to them. It is known that even plants, very sensitive to cold, can endure lowering of the temperature down to several degrees below 0 degrees C because of supercooling of intracellular water. Cryodamages of such plants outdoors occur at temperatures between-2 a n d - 5 degrees C, and result from the ice crystal growth from supercooled intracellular water. However, if the same plants are grown under sterile conditions, precluding ingress of bacteria onto their surfaces, then even cooled down t o - 8 degrees C, no crystallization of intracellular water (thus, no damage) occurs. The treatment with antibiotics (streptomycin or tetracycline), by killing bacteria, also substantially helps improve the frost resistance of plants. Scientists have established that the protein contained in the membrane of these bacteria possesses a unique property to bind water molecules by assembling them into a configuration, similar to that present in ice crystals. As a result, microscopic crystals appear on the membrane of bacteria, and serve as nucleating centers for crystallization of all intracellular water. The capacity to facilitate ice crystallization has been shown to be present but in very few species of bacteria. Thus, out of 42 species of bacteria collected from hawthorn leaves, just one species, Pseudomonas syringae van Hall, exhibited these properties. Yet, not every bacterium of the species contains the unique protein-water crystallizer in its membrane. It is believed that the bacteria that serve as nucleating centers for ice crystallization can have a crucial role in setting the climate of an area by controlling the temperature of crystallization of atmospheric moisture.
Inhale Deeper
"Pure air, in passing through the lungs, undergoes then a decomposition analogous to that which takes place in the combustion of charcoal," Antoine L. Lavoisier (from Leicester and Klickstein, 1952). Indeed, what but a continuous combustion can account for the fact that our body temperature is constant and almost always higher than the ambient one? Lavoisier believed that the "stove" which warms a man is found in the lungs. He claimed that, like in an ordinary stove, the carbon of the living tissue undergoes a chemical reaction with the oxygen in the air to yield carbon dioxide, and as a result, the necessary heat is released. In reality, the reaction involving oxygen occurs not only in the lung cells, but also in all the cells of an organism, where oxygen is delivered by blood. Besides, the process involving oxygen and supplying us with energy (including heat) has nothing in common with the reaction of the direct combustion of carbon, but rather is a long chain of chemical reactions yielding CO2 as one of the end products. Yet for simplicity, our organism can sometimes be regarded as a stove that uses about 0.5 kg of oxygen a day, and which gives off an almost identical amount of carbon dioxide. To further draw on Lavoisier's analogy, the lungs in the stove are assigned the part of an ash-pit for oxygen to enter and a pipe for carbon dioxide to escape.
z
zyxwvu 81
82
Chapter 4. Inhale Deeper
Interestingly, in the seventeenth century the well-known English physicist Robert Boyle (1627-1691), who discovered one of the laws of gases, stated that in passing through the lungs the blood "is freed from harmful evaporations." How do lungs, which take up only about 5% of our entire body volume, manage to fulfill the task? The inner space of a lung communicates with the atmosphere via ducts that comprise the nose, where inhaled air is warmed up and humidified; larynx; trachea; and two bronchial tubes, which feed air to the right and left lungs. Each bronchus may undergo 15 or more branchings, splitting into smaller bronchi, to end with microscopic follicles (alveoli) shrouded in a dense network of blood vessels. Alveoli, of which there are about 300million in an adult, represent bubbles filled with air. The average diameter of alveoli is roughly 0.1 mm and their walls are 0.4/lm thick. The total surface of alveoli in the lungs of man amounts to about 90 m 2. At any single moment, the blood vessels enlacing alveoli hold approximately 70 mL of blood, where carbon dioxide diffuses into alveoli, and oxygen diffuses in the reverse direction. Such enormous surface of alveoli makes it possible to diminish the thickness of the blood layer that exchanges gases with intra-alveolar air down to 1 ILm, which allows for saturating this amount of blood with oxygen and ridding it of the excess of carbon dioxide in less than 1 second. It should be noted that the human in-breath is effected not only by lungs, but also by the entire body surface m the skin, from head to toes. Especially intense is the breathing of the skin in the breast, back, and abdomen areas. Interestingly, these sections of skin are much superior to lungs in the intensity of breathing. Thus, for instance, a unit of the surface of such skin can adsorb 28% more oxygen and give off 54% more carbon dioxide than lungs. This superiority of skin over lungs may be due to the fact that our skin breathes clean air, whereas our lungs are ventilated poorly (see the following section "Exceptions to the Rule"). However, the share of skin in man's breathing is negligible as compared to lungs since the total surface of the human body falls short of 2 m 2, thus constituting less than 3% of the total surface of the lung alveoli. When we inhale, the volume of air in our lungs increases as the air from the atmosphere comes in. Since alveoli are the most elastic part of a lung,
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Breathing and Soap Bubbles
zy zyxwv 83
practically all changes in lungs volume under inhaling and exhaling occur as a result of the respective changes in alveoli volume. In inhaling, alveoli expand and in exhaling they shrink. About 15,000 times a day we extend the alveoli of our lungs, whereby we deliver mechanical work that comprises between 2 and 25 % of all our energy outlay. What determines the amount of this work? The work we deliver in breathing is spent on overcoming the forces of resistance of several types. The first and the most sizeable part is spent on extending the lungs. The second one is the work spent on moving the air in the direction of alveoli. The air flow may be either laminar or turbulent, and the energy expenses depend on which of the two it is. The structure of the nasal cavity is conducive to the turbulent flows of inhaled air. As is the case in a centrifuge, turbulent air flow yields a more efficient warming up of the air and separation of alien particles. Turbulence of inhaled air flow also arises at numerous sites of bronchial tree branchings. Since laminar gas motion transforms into the turbulent one with the increase of the air flow velocity, obviously, the relative role of resistance forces in breathing will depend on the frequency of the latter. It has been shown that the frequency at which we normally breathe (about 15 breath intakes a minute) is consistent with the minimal energy outlay for breathing.
Breathing and Soap Bubbles In 1929 the Swiss physician Kurt von Neergaard demonstrated that the pressure required to distend the lungs could be radically reduced if lungs were filled with the salt solution, which is close in composition to intercellular liquid (Figure 4.1). If every alveolus is considered to be a hollow ball enclosed with an elastic membrane, the air pressure required to sustain the ball in a distended state should be fully determined by the ball diameter, membrane thickness, and Young's modulus, but should not depend on what the ball is filled with. Von Neergaard came to the conclusion that the alveoli normally have a wet lining and therefore the force of surface tension must add to their elastic recoil. To assess the role of surface tension in mechanics of alveoli, consider a sphere-shaped film of liquid. As in the case of a flat film, the surface tension forces here seek to reduce the surface of the sphere by compressing the air
84
Chapter 4. Inhale Deeper
mL
1
[/.~ I
(a)
200 150 100 50
0
i
0.5
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i
i
1.0
1.5
2.0
kPa
I=I G U R E 4 . 1 . Pressure-volume curves for cat lungs filled with air (a) and an aqueous solution (b). (Modified from Radford 1954. Reproduced by copyright permission of Academic Press.)
zyx
inside it. As a result, the air pressure inside the sphere formed by liquid film always turns out to be somewhat greater than the atmospheric one. According to the law of Laplace, the magnitude of increment AP is
AP -
47/R,
(4.1)
where R is the sphere radius and 3'- is the surface tension equal for water at 293 K to 72.8 mN/m. Let us use Eq. (4.1) to find the magnitude of excess pressure required to distend alveoli in inhaling. Let the value 7 for the liquid lining the inner surface of alveoli equals 50 mN/m, which corresponds to the surface tension factor of intercellular liquid. Assuming R = 0 . 0 5 m m , we obtain AP = 4 kPa. Actually, Eq. (4.1) yields a twice higher value of AP, since the alveolar film of liquid is in contact with the air with one (inner) side only. Therefore, the true value of AP will be close to 2 kPa. The comparison between this value and the values of pressure required to distend a lung (Figure 4.1) makes it
It's Not So Simple
85
clear that at least a sizeable fraction of the pressure, if not the whole of it, is spent on overcoming the forces of surface tension. Consequently, the difference between the two curves in Figure 4.1 is what contributes surface tension forces to the elasticity of a lung. In normal inhaling, lung volume roughly increases to 40-50% of their maximal volume. As Figure 4.1 shows, within this interval of the lungs distension, the contribution of surface tension forces comprises between 60 and 80%.
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It's Not So Simple Thus to a great extent, elastic recoil of a lung depends on surface tension forces. It is yet to be understood why the contribution of surface tension grows with the increase of the volume of a lung (see the exhale curves in Figure 4.1), although following Eq. (4.1), the value of AP should decrease with growing R. Besides, why is the contribution of surface tension dependent on a breathing phase (see the curves for exhale and inhale in Figure 4.1)? So far, we have a priori assumed the surface tension factor in different alveoli to be identical and independent of the state of the alveoli (distended or collapsed). Indeed, for pure liquids, surface tension factor is independent of the surface size. However, for a liquid that contains dissolved material, the molecules of the solute may accumulate spontaneously at the surface of the liquid, lowering its surface tension. Substances that act in this way are called surfactants. Some surfactants have such small solubility in a liquid that once their molecules have entered the surface, they do not leave it easily. As a result, if the surface area of the liquid is decreased, the surfactant molecules get crowded together and lower the surface tension to very small values. Surface tension is then a function of surface area. If the concentration of surfactant is high and the substance can cover the entire surface of water in a continuous layer, then 7 of such liquid equals ~ of surfactant. When surfactant concentration is insufficient for covering the entire surface, the surface tension of the liquid will fall in between the corresponding values for water and surfactant. In these cases, the increase of the surface of the liquid will result in the reduction of the surface concentration of surfactant and in increase of ~/, bringing the surface tension factor nearer to 7water"It is obvious that under the reduction of the surface of the liquid the value of 7 for the
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latter will undergo the opposite changes. Such reasoning permitted John A. Clements to explain in 1957 why the contribution of surface tension grows with the increase of the volume of a lung (for review see Clements, 1997). In Figure 4.1, we can see that when lungs are filled with air, the plots, while coinciding at end points, have differing values in intermediate points. We obtain a so-called hysteresis in the dependence of surface tension on area, whereby, the higher the frequency of inhale-exhale cycles, the more pronounced the hysteresis is. The lung surfactant consists primarily of phospholipids (80-90% of its mass). In addition, there are at least four distinct surfactant-associated proteins, SP-A, SP-B, SP-C, and SP-D. The phospholipids have been identified as the primary surface tension-lowering component. With the chemical composition of the lung surfactant having been established, it became possible to study the properties of a film of the surfactant that forms on the surface of water. The results of the experiment, shown in Figure 4.2, illustrate the dependence of surface tension of the surfactant film on the mean molecular area. It can be seen that, with the film shrinking, when the surface per one surfactant molecule diminishes, surface tension gradually lowers and finally levels. With increasing surface of the film, surface tension grows, closing the hysteresis loop, similar to the one in Figure 4.1. What is the underlying cause of hysteresis in Figures 4.1 and 4.2? Why is it that, with the same surface of the film, the value of 7 in inhale always exceeds that in exhale? It is related to the fact that some part of the surfactant, lowering surface tension, is situated not on the water-air interface but dissolved in deeper layers of the liquid that lines alveoli. This amount of surfactant dissolved in the bulk of liquid is in a dynamic equilibrium with surfactant molecules on the surface. However, this equilibrium is not attained instantaneously. Therefore, for instance, at the beginning of inhale, swift growth of the surface is accompanied by an abrupt increase of ~/, since the surfactant dissolved in the bulk is late in coming to the surface. The equilibrium between surfactant molecules is attained only at the end of inhale (exhale), which explains the presence of hysteresis in the dependence of 7 on the surface area. Why does the surfactant have so many components? Probably the most important property of the surfactant is to lower surface tension quickly; that is, to form a stable film rapidly when the surface area is changed. Although phospholipid monolayer films can allow low surface tension, the rate of
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surface tension, mN/m F I G U R E 4 . 2 . Surface tension, which depends on the mean molecular area for a mixed phospholipid and SP-C (0.4mo1%) film. (Modified from von Nahmen et al., 1997. Reproduced by copyright permission of The Biophysical Society.)
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surface adsorption to form monolayers and the spreadability of phospholipids at air-water interface are low compared to those of a natural lung surfactant (Notter et al., 1980). However, as recently demonstrated in several studies (see for example, Taneva and Keough, 1994) the hydrophobic surfactant-associated proteins SP-B and SP-C enhance the surface-seeking properties of phospholipids. An advantage of having the proteins embedded in or in associated with the phospholipid matrix at low 7 may be aiding in the rapid respreading and replenishment of the monolayer with the lipid upon expansion. The proteins get squeezed out of the monolayer at lower 7, but because some small amounts of proteins may remain in the monolayer at low 7 they could rapidly respread the lipids from highly compressed collapsed-phase states. Although the exact nature of the lipid-protein interactions is currently unresolved, some studies suggested that interaction of long protein alpha-helices with anionic lipid headgroups might be underlie the crucial role of the proteins in the lung surfactant (Longo et al., 1993). Where do the substances that lower surface tension and thereby facilitate breathing in a lung come from? It turned out that they are synthesized by special cells in alveoli. The synthesis of these surfactants is underway for the
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whole life of a man, from his birth till his death. In those rare cases when in a newborn's lungs there are no cells producing surfactants (respiratory distress syndrome), a baby is unable to take its first breath by itself and dies. Unfortunately, about half a million newborn children all over the world die every year without taking their first breath because of a shortage or absence of a lung surfactant in their alveoli. Shortly after the lung surfactant was isolated and characterized, attempts were made to treat respiratory distress syndrome of a newborn with aerosols of this substance. The treatment is now standard around the world (Poulain and Clements, 1995).
Exceptions to the Rule However, many animals that breathe with lungs feel perfectly comfortable without any surfactants in their alveoli, for example, the cold-bloodedm frogs, lizards, snakes, crocodiles. Since these animals don't have to spend energy on heating their bodies, their oxygen demand is roughly an order of magnitude lower than that of warm-blooded animals. This is exactly why the lung area used for gas exchange between blood and air is smaller in coldblooded animals than in warm-blooded. Thus one cm 3 of air in the lungs of a frog has a mere 20 cm 2 surface of contact with blood vessels, whereas in man the same air volume exchanges gases with blood through the surface of about 300 cm 2. The relative decrease of lung area per unit of its volume in cold-blooded animals is due to the fact that diameter of their alveoli is roughly 10 times that of warm-blooded animals. Notice that the law of Laplace implies that the contribution of surface tension forces is in inverse proportion to the alveoli radius. Therefore, the large radius of alveoli in cold-blooded animals renders their distension easy even in the absence of surfactant on their inner surface. Birds are another group of animals with no surfactants in their lungs. Birds are warm-blooded animals and lead rather active lives. Energy outlays of birds and mammals of the same weight are similar, as is their demand of oxygen. A bird's lungs possess a unique capability of saturating blood with oxygen in flight at a great height (about 6000 m), where its concentration is half that at sea level. Any mammals (including man), once at such a height, begin to
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experience lack of oxygen and radically scale down their motional activity, sometimes lapsing into a subconscious (comatose) state. How do the lungs of a bird, without a surfactant, manage to breathe and saturate blood with oxygen better than the lungs of mammals? Let us engage in some self-criticism. What is wrong with our lungs? First, not all the inhaled air takes part in a gas exchange with blood. Namely, the air left in trachea and bronchi at the end of inhaling is unable to give oxygen to blood and take carbon dioxide out of it since there are almost no blood vessels there. For this reason, the part of the lungs' volume taken up by trachea and bronchi (along with the volume of the upper respiratory tract) is usually called dead space. Typically, the dead space in human lungs has a volume of about 150cm 3. Notice that the presence of this space not only prevents a corresponding amount of fresh air from accessing the inner surface of alveoli, abundant in blood vessels, but also reduces the average oxygen concentration in the part of air that has reached alveoli. It occurs due to the fact that at the start of each inhaling the alveoli are filled with the dead space air, which is the last portion of the air that has just been exhaled. Therefore, the oxygen concentration in the air that enters alveoli at the start of inhaling is low, and does not differ from that in exhaled air. We can artificially increase the dead space volume by breathing through a long pipe. You will likely notice that the depth (volume) of breathing in this case must be increased. Evidently, if a dead space volume is made equal to the maximal possible inspiration (i.e., about 4.5L), a person will start gasping in several breaths as there will be no fresh air at all to enter the alveoli. Thus, the existence of dead space in the respiratory system of mammals is clearly a miscalculation on the part of nature. While creating the lungs of mammals, regrettably, nature made another mistake m t h e air motion in lungs changes direction in its transition from inhaling to exhaling. Therefore, roughly half of the time the lungs are practically idle since no fresh air enters the alveoli during the exhaling phase. As a result, at the end of exhaling the oxygen concentration in the alveolar air diminishes one and a half times compared to that in the atmosphere. Since during inhaling the oxygen-rich inhaled air mixes in the alveoli with the air already there, the resulting mixture, which will exchange gases with blood, contains oxygen in a smaller concentration than that in the atmosphere. Therefore, blood oxygenation in mammals will always be
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less intense than in a hypothetical case where the air would pass through the lungs all the time in the same direction regardless of the breathing phase. Of course, in the lungs of mammals with the trachea serving for both air entry and exit at once, this unidirectional motion of breathing mixture is unfeasible. Meanwhile, in birds nature again reached perfection. Besides normal lungs, birds have an additional system composed of five or more pairs of airbags connected to lungs. The cavities of the bags have many branches in the body, entering some bones, sometimes even the fine ones. As a result, the respiratory system in a duck takes up about 20% of body volume (2% lungs and 18% air bags), whereas in a human, a mere 5%. Airbags not only reduce the body density but also promote the blowing of air through the lungs in a single direction. The only thing that changes in birds' breathing is the volume of airbags, whereas the volume of a lung remains practically constant. Because there is no need to expand the lung, it becomes immediately clear why there is no surfactant in birds' lungs--it would just be of no use there.
Countercurrent: Cheap and Effective Seeking to maximally increase the oxygen concentration in the blood of birds during their flights at great heights, nature resorted to yet another contrivance: the direction of blood motion in birds' lung vessels is the opposite of that of the air current through a lung. Such countercurrent manner of blood oxygenation is much more efficient as compared to the case when the blood and the air move through lungs in the same direction. Let us demonstrate it with the following example. Assume that two tubes, which simulate the adjacent blood vessel and the air-carrying tube of a bird's lung are in contact with each other along a certain segment (Figure 4.3). The surface of contact between the blood vessel and the air-carrying tube enables oxygen to diffuse from air into blood, with carbon dioxide diffusing in the reverse direction. The blood that is about to leave the lung (the right-hand part of Figure 4.3) is in contact with the air that has just entered the lung, in which oxygen concentration has not yet been lowered. As the air passes through the lungs, it loses oxygen and takes in carbon dioxide. Therefore, moving along the vessel, blood comes in contact with the increasingly oxygen-rich portions of
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Countercurrent method of blood oxygenation in bird lungs.
fresh air, which provides it with the opportunity to be oxygenated to the greatest possible extent. The same mechanism enables blood to get rid of excessive carbon dioxide faster than it happens in mammals. Interestingly, nature employed the countercurrent system not only in birds, which encounter lack of oxygen in the flights at great heights, but also in the gills of fish, which use oxygen dissolved in water, where its concentration is roughly 1/30 of that in the atmosphere.
Diving In man and other higher-organized animals, breathing and the beat of the heart are synonymous to life. Heart and lungs supply an animal with the required amount of energy, deliver oxygen to tissues, and remove carbon dioxide from them. For this reason cessation of breathing or of blood circulation represents a great danger for the life of an animal. However, not all tissues need uninterrupted oxygen supply to the same degree. If blood circulation in a hand or a leg is stopped with a tourniquet for an hour or even longer, it will cause no damages to the tissues of these organs. Kidneys can also endure interruptions in blood supply. Unfortunately, the heart and the brain are highly sensitive to the lack of oxygen. Therefore, asphyxia or cardiac arrest that lasts several minutes results in irreversible changes in the respective tissues. It is known that cats, dogs, rabbits, and other land mammals die several minutes after they have been completely submerged in water. Ducks, however, can endure 10-20minutes of submersion underwater; seals, 20 minutes and longer; some species of whales, more than an hour. How can they do it?
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Experiments performed on seals have shown that during diving the cardiac rhythm in these animals sharply slows down (to 1/10 of normal rate). This occurs right after submersion of their nose openings underwater. The same event takes place in penguins, crocodiles, tortoises, ducks, and all other animals who breath air, but spend part of their time underwater. It is of interest here that in flying fish, whose gills stop working when the fish leap out of water or are forced out of it, heart contractions noticeably slow down as well. Such sharp deceleration of the cardiac rhythm under conditions of oxygen deficiency in all these animals enables a radical reduction of oxygen consumption by the heart, which is the main oxygen user in an organism (for review see Butler and Jones, 1997). In diving, for the blood supply of the heart and brain not to fall below the permissible level, the diameter of vessels in other organs (except the heart and brain) decreases noticeably. Therefore, even at a slow rate of heart contractions, the oxygen supply of the heart and the brain in diving animals is still sufficient. The same regulating mechanism of blood circulation in diving is developed in training pearl divers, who are known to be able to stay underwater for several minutes, at a depth of up to 30 m. What about us, ordinary people, who do not have the capabilities of pearl divers? How can a common man investigate the mysteries of the sea depths? The world's ocean, with the average depth of about 3 km and the area comprising 70% of the planet's surface, is still practically unexplored. And, though in 1960 the bathyscaph Trieste descended 11 km to the deepest part of the ocean, at present there are fewer footmarks left by man even at a depth of 1 km than on the surface of the moon. The first contraption for a continued stay of man underwater seems to have been a long pipe connecting his mouth to the atmosphere. A breathing pipe was already used by ancient Greeks and Romans. Leonardo da Vinci (1452-1519) improved a breathing pipe, supplying it with a cork disk placed so that the upper end of the pipe always extended above the water and a person could breathe freely. The length of the pipe was up to a meter. Leonardo da Vinci's pipe was intended not for underwater swimming but rather for "walking under the water." The great scholar thought that the contraption could be used in the Indian Ocean to "mine for pearls." It is of interest that a breathing pipe of a kind is found in larvae of some insects living at the bottom of puddles and shallow ponds. By thrusting their pipe up
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to the surface of water, they have the possibility to breathe without getting out of mud. Judging by James F. Cooper's novels, the Indians often resorted to a breathing pipe: as they were hiding from their enemies under the surface of water, they were breathing through a hollow reed. However, this method of breathing underwater is possible to use only when the depth of submersion does not exceed 1.5 m. At a greater depth of submersion, the difference between the water pressure compressing the chest and the air pressure inside it increases so much that we are already unable to increase the chest volume in inhaling and fill the lungs with fresh air. Therefore, while at a depth greater than 1.5 m, we can only breathe the air compressed to the pressure equal to that of water at this depth. To this end, skin divers take along compressed air bottles. However, descent to different depths requires different pressure of inhaled air. Thus, at a 10 m depth the pressure must equal 200 kPa, and at a 40m depth,-500 kPa. Therefore, a skin diver should continually monitor the depth of descent and change the inhaled air pressure accordingly. Unfortunately, the experience of using Aqualungs has shown that they can be used to descend to a depth less than 40m. At a greater depth, a skin diver would have to breathe air that would be compressed to a pressure in excess of 500 kPa, and would have an oxygen concentration more than five times that of the atmosphere, which would cause oxygen poisoning. A person can breathe pure oxygen at the atmospheric pressure for about 24 hours only. A longer period of breathing oxygen brings on pneumonia, terminating in death. A person can breathe pure oxygen compressed to 200300 kPa for one and a half to two hours at most. Afterwards, he or she suffers disturbances of coordination of movements, as well as attention and memory disturbances. To preclude the toxic effect of oxygen, skin divers who descend to a great depth are supplied with special breathing mixtures, where the oxygen percentage is lower than that in the atmospheric air. However, at such high pressures, the nitrogen in the breathing mixture can produce a narcotic effect. In addition, breathing nitrogen-bearing mixtures at a depth of about 100 m is very hard, as the density of inhaled gas compressed to the pressure of 1000 kPa is ten times that of the atmospheric air. Such a high density of inhaled gas transforms an otherwise easily performed act of breathing into a process of the labored "pushing" of air into the lungs. Therefore, as a rule, at
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depths below 40 m divers breathe a mixture of oxygen and helium. Helium has no narcotic effect at such high pressures and its density is approximately 1/7 that of nitrogen. Yet divers descend deeper and deeper. They often have to mount and replace oil rigs at sea where oil is the cheapest since it occurs at a shallow depth. The deep-sea divers who mount rigs in the North Sea at times have to work at a depth of about 300 m and breathe gas mixtures compressed to a pressure of 3000 kPa. Nonetheless, hardships (and even dangers) lie in wait for a skin diver that has descended to a great depth not only underwater, but also right after he or she comes up to the surface. Long ago it was already known that deep-sea and skin divers who quickly ascend from a great depth soon begin to experience intense pain in their joints. This occupational disease of divers became known as decompression illness. It turned out that the unpleasant sensations in the joints of divers who had just ascended from depth were due to formation of gas bubbles in tissues. The gas bubbles can also be the cause of clogging of small blood vessels. In its 1997 edition of Report on Decompression Illness and Diving Fatalities, Divers Alert Network states that the number of reported cases of decompression illness that occurred in the diving year 1995 was 1132, including 104 fatalities from recreational dives. Decompression sickness results from gas coming out of the solution in the bodily fluids and tissues when a diver ascends too quickly. This occurs because decreasing pressure lowers the solubility of gas in liquid. Rapid ascent may lead to bubble formation. The bubbles emerge in the same way as they do in a soda water bottle once it is opened. In both cases, the bubbles arise under lowering of pressure above the liquid saturated with gas at high pressure. Henry's law and Dalton's law are central to understanding decompression sickness. Henry's law states that, at a given temperature, the amount of gas that will dissolve in a liquid is directly proportionate to the partial pressure of the gas. Dalton's law states that the pressure of a gas is the sum of the partial pressures of all gases present. Decompression illness is also possible at a quick climb to a height in an unsealed chamber. In this case, the danger of decompression illness arises due to a sharp drop in pressure roughly by 50 kPa (at a height greater than 6000 m). Several cases of decompression illness have been recorded in pilots flying in an unsealed cabin at an altitude of about 2500 m. However, on the
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day preceding the flight all these persons went skin diving with the use of an Aqualung. Obviously, before the flight the organism of each pilot contained small air bubbles, which started expanding and were perceived by the pilots upon an insignificant decrease of the atmospheric pressure. Therefore, pilots are recommended to get behind a steering wheel of an airplane at least two hours after skin diving. For a bubble to be formed at the site where it has not been before, its evolution should, obviously, pass through two different phases: 1) the formation of the tiniest bubble at the site where "there was nothing," and 2) bubble growth. Gas bubble growth at a sudden drop of atmospheric pressure is easily explicable with the help of Boyle's law. The mechanism of the tiniest gas bubble formation "out of nothing" has so far been studied insufficiently. It is believed that under normal conditions there always are so-called micronuclei present in body tissues. Those may be the precursors of decompression illness bubbles. The presence of micronuclei appears to be necessary for the bubble formation process, as in pure water, when gas bubbles fail to form at all even at a sudden thousandfold drop of gas pressure above its surface. Possibly such nuclei might include stable (retaining their size) gas bubbles present in tissues, whose selected mechanisms of stabilization were examined by van Liew and Raychaudhuri (1997). They reviewed the mechanisms that can overcome the absorptive tendencies, so that small spherical bubbles can persist. One general type of stabilizer is a mechanical structure at the gas-liquid interface that can support a negative pressure so that gases inside can be in diffusion equilibrium with their counterparts outside. One possibility for such a mechanical stabilizer is surfactant films. Decompression illness can be avoided if a diver is lifted from a great depth slowly enough, with necessary pauses. Such pauses in the ascent enable dissolved gas to diffuse through tissue to blood vessels. From there it passes into lungs along with the blood flow, and then further into the atmosphere, having failed to form bubbles. It is believed that decompression illness does not develop at a sudden ascent from a depth less than 9 m. To reduce the decompression illness risk as much as possible, the diver has to adhere to one of the safe diving practices and select an appropriate dive profile and decompression table. For example, according to the National Association of Underwater Instructors, the stay at a 24 m depth for an hour makes it necessary to stop during the ascent at a depth of 5 m for 17 minutes.
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In the cases when the divers work daily at depths in excess of 100 m for all working hours, it has been considered expedient that the pressure of the air they inhale not be lowered even in a recreation period after the ascent from the depth, as it would require several hours. Therefore, in the interval between descents they rest in special hyperbaric chambers installed on board ships. The greater part of gas bubbles is formed by nitrogen, for oxygen is intensely consumed by body cells. The danger of decompression illness development can be reduced if instead of nitrogen helium is used, which is 36% less soluble in blood plasma and 76% less soluble in fats. Besides, the diffusivity of helium through body tissues is almost three times that of nitrogen. Great diffusivity of helium permits a shorter duration of a diver's ascent to the surface. It turned out, however, that helium-oxygen mixtures ensure the normal work of divers only to a depth of 400-450 m. At further increase of pressure the mixture density becomes very high, which renders breathing impossible. Much is expected of the inclusion of h y d r o g e n - - t h e lightest gas in the mixture for divers. Naturally, a gas mixture containing hydrogen and oxygen simultaneously is explosive. However, the probability of mixture explosion is very small, as the ratio of oxygen and hydrogen volumes is far from the explosive one (1:2). At the same time, on the surface, where the gases are stored and mixed, the probability of explosion is much greater, which requires the undertaking of necessary precautions. To explore the relative dangers of different inert gases, the effects of physical properties of the gas on decompression-sickness bubbles were studied using a mathematical model (Burkard and van Liew, 1995). However, the task of finding the optimal gas mixture, which could let deep-sea divers master depths exceeding 500 m, is still unresolved. There is yet another phenomenon related to the formation of gas bubbles in liquids at a sudden lowering of external pressure. In our nervous age, it is rather common to crack our fingers in minutes of agitation. For a very long time, the cause of the cracking sound when pulling joints has remained unknown. Many believed that it was the clicking of bones. Upon a detailed study, however, it turned out that the cause of these cracking sounds was gas bubbles that formed and burst in the liquid filling the sinovial capsule. When a joint is pulled, the volume of the sinovial capsule increases, the pressure in it drops accordingly, and the fluid lubricant in the joint boils up. The forming gas bubbles merge with the larger ones and burst with a pop. When the
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bones return back to normal position, the gas is gradually absorbed by the liquid. This takes place for about 15 minutes. After this time, it is possible to crackle the joint again. All of these difficulties related to the stay of man underwater arise because compressed air is breathed. What if a person is made to "breathe" water as fish do? Of course, oxygen concentration in water at equilibrium with the atmosphere amounts to less than 5 percent of that in the air. But even this concentration, when in contact with blood, will be enough to saturate the latter with oxygen to a normal level. In addition, the oxygen concentration in "inhaled" water can be increased by continuously passing pure oxygen through it rather than air. Obviously, in "breathing" water containing dissolved oxygen, there is already no need to compensate for the increase of external pressure in descent since according to Pascal's law the pressure of water inside lungs will always equal the outside pressure. Therefore, the efforts required to inhale will not change with the depth of descent. Using water as the carrier of dissolved oxygen saves one from the danger of oxygen poisoning, for the oxygen concentration in "inhaled" water can be made constant and equal to that in the atmosphere. For the same reason, the danger of decompression illness does not exist anymore. With the help of a special apparatus, dogs and mice were able to live "breathing" water for several hours. They died because the concentration of carbon dioxide in their blood grew beyond the permissible limit. Thus, "breathing" water, animals completely met their demand in oxygen but were unable to remove the forming carbon dioxide efficiently. In mammals under normal conditions (at rest), each liter of exhaled air contains about 50 mL of CO2, whereas the solubility of this gas in water is such that each liter of it under the same conditions can contain no more than 30 mL of CO2. Therefore, to remove all the carbon dioxide forming in an organism, it is necessary to pump through the lungs almost twice as large volumes of water as the required volumes of air. According to Bernoulli's equation, the difference of pressures needed for moving liquid (or gas) medium through a pipe of the known length and diameter at a certain velocity, must be proportionate to the viscosity of the medium. And as the viscosity of water is roughly 30 times that of the air, unaided "breathing" of water will require approximately 60-fold energy outlay. Since nature endowed us with the lungs that are useless in sea depths,
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to explore these depths we need bathyscaphs and submarines. But is everything really that hopeless? In 1966, Clark and Gollan established the remarkable gas exchange qualities of perfluorocarbons (PFC)m liquids that are structurally similar to hydrocarbons, with the hydrogen replaced by fluorine. Their experiment involved submersing spontaneously breathing mice in the PFC. The animals sustained life while immersed in the liquid and survived after their return to gas breathing. This experiment was the breakthrough required for further investigation of the use of PFC for support of gas exchange in the lung (for review see Sadowski, 1996). PFC liquids have many qualities that are unique and that make them perfect for liquid ventilation. PFC liquids are nontoxic, odorless, and aren't absorbed by tissues. PFC liquids have 16 times the oxygen solubility and 3 times the carbon dioxide solubility of water. This gives PFC liquids an excellent oxygen and carbon dioxide carrying capacity: 50 mL of oxygen per dL and 160-210 mL of carbon dioxide per dL. PFC liquids have a slightly smaller carrying capacity of oxygen compared to that of blood: up to 200 mm Hg. But beyond 200 mm Hg, PFC liquids are actually better. Another trait that makes PFC liquids suitable for liquid ventilation is a very low surface tension (approximately 18-19 mN/m). When instilled, the PFC spreads into the collapsed alveoli where gases have been unable to penetrate before. It lines the alveolus, stabilizing and re-expanding it. PFC liquids are twice as dense as water; therefore, liquid ventilation requires the use of a mechanical breathing device to assist breathing. More recent research in animals and limited studies in humans have shown that oxygen-carrying fluorocarbons have the potential to improve pulmonary function in both infant and adult respiratory distress syndromes. Further biophysical studies are needed to optimize delivery of the fluorocarbons and their adjunctive use with mechanical ventilation.
High Frequency Ventilation and Einstein's Formula The techniques of resuscitation of organisms must have always interested people. Apparently, the earliest of survived methods of mechanical
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ventilation is contained in the book De humani corporis fabrica (1543) by the medieval Flemish anatomist A. Vesalius (1514-1564), a founding father of anatomy. At those times, reviving departed souls was considered a seditious business, so Vesalius, persecuted by the church, explains in one of his books how to apply mechanical ventilation to pigs. His views on functions of various bodily organs were condemned as heresy and he had to undertake a pilgrimage to Palestine, never to return, dying in a shipwreck. It is interesting that in the same year, Copernicus published his historic treatise De revolutionibus Orbium Caelestium that made a breakthrough in natural science. The same year provided mankind with a possibility to change its views radically on man and the universe. But this failed to happen, and both geniuses were declared heretics. However, the progress of knowledge cannot be stopped, and a century later (1667) Robert Hooke (1635-1703), known to many of us as a physicist, reproduced almost word for word the method of mechanical ventilation described by Vesalius. Many years have since passed, and today the technique of mechanical ventilation enjoys wide application in clinics during surgery and in first aid for reanimation of seriously ill patients. Modern lung ventilation units present a pump to force breathing mixtures (for severe cases, pure oxygen) into the patients' trachea. The pump has special valves, Vl and V2 (Figure 4.4); the first is for connection of the pump and lungs in inhaling and disconnection in exhaling, and the second is for connection (during exhaling) and disconnection (during inhaling) of trachea and the atmosphere. Are physicians happy with such an artificial lung? Not always. Patients often develop post-surgical complications such as pneumonia. This is attributed to the rupturing of the alveoli during mechanical ventilation. But why do the alveoli not rupture when we breathe on our own? As we know, lungs are enclosed on all sides with an airtight pleural cavity filled with air, the latter connecting the former mechanically with the thorax. In unaided breathing, the muscles of thorax, contracting at the beginning of the phase of inhaling, cause its volume to increase so that the pressure inside the lungs drops below the atmospheric one, and a fresh portion of air enters the lungs through the trachea. Therefore, it is obvious that in this unaided inhaling, the pressure gradient between the inner and outer cavities of each alveolus will be determined solely by its elastic performance and the characteristics of surfactants.
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F I G U R E 4 . 4 . Schematic representation of conventional mechanical ventilation. V1 and Vz are the valves changing the direction of air flow through the lungs.
Under mechanical ventilation, the air pressure inside an alveolus in inhaling should not only insure its adequate distension but also increase the volume of the entire thorax. Thus, under mechanical ventilation, the thorax enclosing the lungs represents a substantial obstacle that entails the significant increase of the the air pressure in inhaling. The measurements have shown that in unaided breathing with a frequency of 14 inhales a minute and a volume of 0.5 L, the excess pressure inside alveoli never exceeds 0.1 kPa, whereas under mechanical ventilation it may be as high as 0.5-1.0 kPa. The result of the growth of air pressure in alveoli is their ruptures and subsequent complications. What can be done to make mechanical ventilation safer? The solution is self-evident: the tidal volume must be decreased and, at the same time, the breathing frequency must be raised. Indeed, by diminishing the distension of lungs, we decrease the magnitude of the excess pressure in them, and, consequently, the probability of their rupture. However, to use this method of optimization of mechanical ventilation, one has to know the interrelation of breathing frequency and the tidal volume. It has been established that every minute, 5 L of fresh air must enter a person's lungs in a state of rest. The word "fresh" is highlighted here to
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remind you of the existence of dead space, from where no fresh air enters the lungs. Thus, the following relation between breathing frequency f[1/min], tidal volume Vt[L], and dead space volume Vd holds 5 - (Vt -
Vd)f
(4.2)
To make use of Eq. (4.2), we have to know the numeric value of Vd. We already know that the average Vd of an adult is about 150 mL, but how is the value of Vd to be found for every one of us? In order to do it, it is sufficient for a person to take a single breath of pure oxygen rather than air from the atmosphere. Then the gas composition of exhaled air has to be studied. The analysis of this first exhalation after inhaling pure oxygen is shown in Figure 4.5. The first 100 mL of exhaled air show no trace of nitrogen, which means that this air did not mix with the air in the lungs. Therefore, the volume of dead space in this case can be considered equal to 100mL. Subsequent portions of exhaled air do contain nitrogen, bearing evidence of the gas exchange taken place between the inhaled Oz and the N 2 present in the lungs.
% N2 80
60
-
40
-
20
-
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I
I
I
I
I
I
300 600 expired volume, mL
I
I
900
FIG U R E 4 . 5 . Single-breath N2 curve. (Modified from Permutt et al., 1985. Reproduced by copyright permission of The American Physiological Society.)
102
zy zyxwvutsr Chapter 4. Inhale Deeper
When the validity of Eq. (4.2) came under scrutiny, it proved to be valid only for V t > O . 4 L , while yielding too-high values of f at smaller Vt. Pulmonary and cardiac surgeons came to dislike the formula also because it forbade using V t < 1 0 0 - 1 5 0 m L in mechanical ventilation, because movements of lungs while breathing get in their way as they operate. And so, in the late 1960s, several surgeons at once, forgetting Eq. (4.2) and dead space, decided to cross the forbidden line, let Vt go below 100 mL and . . . succeed. Their patients endured a seemingly inexplicable type of mechanical ventilation perfectly well. Thus, for instance, mechanical ventilation with Vt = 50 mL and frequency 180 m i n - 1 reliably secured vital functions of a human organism at rest. If we substitute the numbers in Eq. (4.2) and evaluate Vd, it turns out that it should equal a mere 20mL. What is Vd equal to, after all? 150 mL or 20 mL? Before answering this question, let us try to answer another one. What role in breathing does diffusion play during the movement of air from the atmosphere into lungs (and back)? Obviously, a very insignificant one. Indeed, it is sufficient to hold your breath for one minute (even after the preliminary breathing of pure oxygen), and an irresistible desire to inhale fresh air arises. What is the way to enlarge the role of diffusion? In the middle of the 1960s the same problem was faced by the scientists dealing with physics of soil, when they set a task to oxygenate deeper layers of earth. Their research, performed on different porous materials, showed that the gas diffusion through these media accelerates significantly in the presence of oscillatory motion of air. Thus, the index of oxygen diffusion through a test container with a porous medium increased four times (compared to standard conditions), whereby a mere 1/200 of volume under study was pumped through it (there and back) at a frequency of 4 Hz. According to Fick's law, gas diffusion coefficient, D, through surface S of a layer of thickness x, can be found from the following relation: D = (V)'[x/S(C, - C2)]
(4.3)
where (V)' is the velocity of the gas diffusion current through the layer, and Cl and C 2 are the concentrations of the gas on both sides of the layer. This equation can, obviously, also be used for measuring the diffusion currents between the lungs and the atmosphere. As a physical model of space
z zyxw
High Frequency V e n t i l a t i o n and Einstein's Formula
103
located between lungs and the atmosphere, Jaeger et al. (1984) used a pipe of 60cm in length and 2cm 2 cross-section area, which corresponds to the average cross-section area of trachea and bronchi and their length. With the help of the model, Jaeger et al. studied the dependence of D on frequency f of longitudinal vibrations of air in the pipe and the amplitude Vt (in mL) of the vibrations. Figure 4.6 shows how D increases with growing f and Vt. It turned out that D is in direct proportion to fand (Vt)2. In addition, direct proportional dependence of D on S-2 was revealed in special experiments. Thus, the empirically found dependence of D on these parameters was of the form
D
-
-
(4.4)
kf(WtlS) 2
where k is a dimensionless factor, close to 0.05, given f is measured in Hz, S in cm 2, and Vt in mL.
14 1000 22 (D
E (o
o 500 "1-
c~
!
I
.5000
10000 Vt 2 , c m 6
F I G U R E 4 . 6 . Results from a bench model. DHFO values, computed with Eq. (4.3), are plotted against the square of tidal volume, (Vt) 2. Frequencies were 2, 5, 14, or 22 Hz and marked near corresponding lines. (Modified from Jaeger et al., 1984. Reproduced by copyright permission of Lippincott, Williams & Wilkins.)
104
Chapter 4. Inhale Deeper
It follows from Eq. (4.4) that gas diffusion coefficient in a long pipe is proportionate to the frequency of vibrations of gas particles and to the squared amplitude of the vibrations. This dependence is very much like the relation derived by Einstein in 1905 for molecular gas diffusion. The diffusion coefficient in Einstein's formula is directly proportionate to the collision frequency of molecules and to the squared length of their free path. Therefore, Eq. (4.4) will coincide with Einstein's formula, if the frequency of vibrations of air column in the pipe is put in correspondence with the collision frequency of gas molecules, and the amplitude of longitudinal vibrations of the column, with the free path length of a molecule. Thus, diffusion and convection currents, arising in a pipe filled with gas, can increase the diffusion coefficient of oxygen by a thousand times. 1 This explains the efficiency of high-frequency oscillatory ventilation. Still there remain some patients who need very low ventilation pressures despite the most sophisticated conventional ventilation strategy. One of the alternatives for these is the high frequency ventilation that differs from conventional positive pressure ventilation in rates greater than 50 breaths/ min and a tidal volume similar or less than dead space. Another alternative is high frequency jet ventilation that uses a pulse of a small jet of fresh gas introduced from a high-pressure source (50 psi) into the airway via a small catheter. The rates here are usually 100-400 breaths/min. High frequency ventilation can be utilized with all patient populations suffering from acute lung injury. Unfortunately, so far no complete theory of the high frequency ventilation has been proposed, which somewhat delays the application of this efficient technique in clinics.
The Physics of Cough Cough is known to arise either as a result of the infectious diseases of the respiratory tract or because of foreign bodies or small particles that have gotten into it. In all these cases, cough serves for discharging mucus and particles that obstruct normal breathing. Evidently, the greater the linear velocity of air escaping trachea during cough, the more effective the cough I Note, for comparison, that D for oxygen diffusion in nitrogen atmosphere with no oscillations amounts to about 0.2 cm2/sec at room temperature.
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The Physics of Cough
105
is. Let us try to evaluate the maximal magnitude of the velocity and sort out on what parameters of the respiratory system it depends. Before coughing, we inhale air into lungs. After that, following an inborn reflex, the glottis is closed (i. e., trachea no longer communicates with the atmosphere), while the contracting muscles of thorax begin to decrease its volume. As a result (as a rule), the lungs' volume diminishes from 6 to 5 L, whereas the air pressure in the lungs increases by 20 kPa. This phase of compressing the air in lungs lasts for about 0.2 sec. Then muscles of the glottis suddenly relax and the compressed air from the lungs escapes outside with a distinctive sound. Figure 4.7 shows how the volume rate of air outflow from lungs changes in time during coughing. The maximal volume rate in this case roughly equals 6 L/sec; however, sometimes it can become as high as 10-12 L/sec, which should be considered its maximum. What leaps to the eye is that the volume rate spike lasts for a very short time (less than 0.1 sec), after which the rate falls off sharply. As Figure 4.7 shows, arising simultaneously with the end of the volume rate spike is the "sound track" of cough. What hinders sustaining the high velocity of air effluence from the trachea for a longer time, and what is the cause of the sound? The answer to the first question would seem to be obvious. A person's thoracic muscles are unable to secure prolonged and sufficiently high compression of air in the lungs. Indeed, the physical capabilities of a person are limited. But let us attempt to simulate the process of air effluence from trachea. Instead of a human trachea, we can examine a trachea of a large animal (such as a dog) or pick an elastic pipe with similar mechanical parameters. Figure 4.8 shows the volume rate of air outflow from such a pipe as a function of the difference of pressures between its ends. The volume rate of air outflow proves to grow with increasing pressure, but it has an upper bound, so that with the pressure beyond 5 kPa the growth of the volume rate stops, whereas at further increase of the pressure the volume rate even starts falling. Strange, isn't it? What about Hagen-Poiseuille's equation? And more generally, where does the energy go? Why does the growing pressure with which we increasingly compress the air in the pipe fail to transform into the kinetic energy of the motion of air particles at the exit from the pipe? The answer is simple. Staring at the plot and speculating quite often proves to be insufficient to explain a physical phenomenon. This is what
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106
Chapter 4. Inhale Deeper
F I G U R E 4 . 7 . Flow at airway opening (flow rate), subglottal pressure, and sound level during a representative cough. (Recordings are modified from Yanagihara et al. 1966. Reproduced by copyright permission of Scandinavian University Press.)
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_o 3
0
~ 3
~ 6
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driving pressure F I G U R E 4 . 8 . Progressive decreases in pressure at the downstream end of excised dog trachea result in increasing flows only to critical condition (arrow). (Modified from Elliott and Dawson, 1977. Reproduced by copyright permission of the American Physiological Society.)
The Physics of Cough
107
happens: with the volume rate of air outflow from the pipe attaining its maximal values, its elastic walls begin to experience compression, now closing, now opening, the passage in the pipe for the air to move. As a result of such oscillations, the average registered velocity of gas outflow ceases to grow with the increase of pressure, and the energy of compressed air transforms into the energy of the strain of pipe walls and, of course, into the heat. Also, we have no reason to question the validity of Hagen-Poiseuille's equation, it being valid for pipes with rigid walls only. Obviously, it is the periodic changes of the velocity of air outflow from trachea that cause the appearance of the distinctive sound in cough. What underlies these oscillations of the velocity of outflow air in cough ? This is not easy to answer. First, let us try to answer the following seemingly silly question: Why should the air particles in the middle of the pipe increase their linear velocity, when the air pressure at one of its ends grows? How do they know of the pressure growth? Of course, from neighbors; and those, in turn, from their neighbors, and so on. In other words, if pressure at one of the pipe ends increases (or reduces), a compression wave travels along the pipe with a certain velocity, thus "informing" of the change in pressure. And as soon as the wave reaches a specific air particle in the middle of the pipe, the particle increases (or reduces) its velocity. What determines the magnitude of the propagation velocity of compression wave? If you have read Chapter 2, "Heart Pulse," perhaps you have already guessed that the velocity of a compression wave that travels along the trachea is determined by the same parameters as velocity 0 of the pulse wave that propagates along a blood vessel (see Eq. (2.1)); that is, by the trachea diameter, its wall thickness, Young's modulus of the tissue it consists of, and the density of air. Now let us imagine that the velocity of air motion along the trachea exceeds 0. How, indeed, would the air particles know that they have to increase (or reduce) the velocity of motion since the compression wave, which used to inform them of it, will never catch up with them? Therefore, it follows that the velocity of air motion along the trachea cannot exceed 0. The measurements of the maximal velocity of air outflow in coughing have shown that the value in question is, typically, below 100-150 m/sec, which agrees with the estimates obtained using Eq. (2.1). There is yet another question to answer: Why do the pipes come under
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108
Chapter 4. Inhale Deeper
compression when the air is passed through them? When we blow air of density p at velocity u through a pipe, pressure (P) inside it can be evaluated using Bernoulli's equation; so, if the losses for viscous friction are ignored, we obtain P = Po - pv2/2
(4.5)
where Po is the atmospheric pressure. Thus, air pressure inside trachea during exhaling and coughing can be less than the atmospheric one; this means the trachea is acted upon by the forces of contraction, which seek to lessen its cross section. One more thing: the properties of a real pipe or of a trachea are not uniform across its length. This means that there is a point in the pipe where the rigidity of its walls is minimal. It is at this point that the trachea opening becomes the smallest possible, with the linear velocity of the air motion increasing accordingly. As Eq. (4.5) shows, this results in an even greater contraction along this section, and so on, until the linear velocity of gas at the section reaches 0. Obviously, when the trachea opening at the least rigid section diminishes noticeably, the loss for viscous friction grows significantly, and cannot be ignored any more. Therefore, the relationship between P and u in this case will not observe Eq. (4.5). The flow of liquids and gases along pipes with elastic walls is a very complicated process. Giving its exhaustive description with the help of vivid and easy-to-grasp examples the way we try to do here, is practically impossible and, perhaps, should not be even attempted. For this reason, I want to place a period at this p o i n t ~ practically in mid-sentence. Those of you who have gotten really interested in the physics of cough, with many questions still unresolved, are referred to the recently published work of Walsh et al. (1995).
Hunt for Cells in an Electric Field
We are aware of the fact that we consist of cells, but we do not attach much importance to this. As far as our health goes, we care more for preserving parts and organs of our body m head, heart, extremities, kidneys, liver, and so on. Meanwhile, the appearance of just one unusual cell, a dangerous virus, or bacterium, can pose a real threat to our life. Therefore, the necessity to study individual cells is also dictated by our purely protective reaction, seeking to learn mechanisms of various diseases in order to fight these unwelcome microscopic visitors. However, it is not just fighting dangerous viruses that stimulates cellular biologists to conduct their research. The very beginning of a new human life, originating in the fusion of two c e l l s - - o o c y t e and sperm m i s still full of mysteries. Even though it has been almost two years since (in 1997) the embryologist Ian Wilmut and his colleagues (at Roslin Institute near Edinburgh, Scotland) managed to create a frisky lamb named Dolly from a cell isolated from an adult ewe's mammary gland, their article in Nature still reads as science fiction. Indeed, Dolly is a carbon copy, a laboratory
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110
Chapter 5. Hunt for Cells in an Electric Field
counterfeit, so exact that it is in essence its mother's identical twin. The ability to clone adult mammals opens up a myriad of exciting possibilities, from producing replacement organs for transplant patients to cloning champion cows. To create Dolly, the Wilmut team faced a necessity to manipulate isolated cells without damaging them. Thus, for instance, at one of the crucial stages of cloning, two cells are placed next to each other, and an electric pulse causes them to fuse together like soap bubbles. Although there exist a number of protocols that can bring cells into contact, there is an obscure but highly convenient phenomenon called dielectrophoresis that can cause cells to become aligned into long chains of cells called pearl chains. This phenomenon is caused when a weak alternating electric field is induced in the aqueous medium containing the cells. This utilizes the same electrodes that carry the fusion-inducing electric pulse. Once cell-to-cell contact is induced, a strong but brief direct current pulse is applied, causing the cells to fuse. The manipulation of living cells in electric fields is now being developed to produce new hybrid cells; in particular, human hybridoma cells (hybrids between B lymphocytes and myeloma cells). The aim is to produce hybridomas secreting human antibodies to clinically important antigens such as Hepatitis B and other viruses. Human antibodies, unlike the already available animal-derived antibodies (mostly from mice), could be used as therapeutic agents. Mouse antibodies cannot be used in therapy in humans as the body's immune system recognizes these antibodies as nonhuman, leading to severe adverse immunological reactions (including death).
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Principles of Dielectrophoresis The possibility of manipulating the living cells in electric field is explained by their dielectrophoresis. Dielectrophoresis is defined as the lateral motion imparted on the uncharged but polarizable particles as a result of polarization induced by nonuniform electric fields (Pohl, 1978). When a polarizable particle (or cell) is exposed to an electric field, the particle polarizes, giving rise to an induced dipole moment. The value of the dipole depends on the particle volume, its permittivity relative to that of the surrounding medium, and the electric field intensity, E. In the case of a
Principles of Dielectrophoresis
111
zyxwv
spherical homogeneous particle of radius r the effective dipole moment, m, can be expressed as in Sauer (1985): m -- 4rcgrrf(g*p, g*m)r3E
where f(e*p,e*m)=(e*p--e*m)/(e*p+2e*m)is the so-called ClausiusMosotti factor, and e*m and e*p are the complex permittivities of the medium and the particle, respectively. A general complex permittivity is given by e* = e - j ( a / ~ o ) , where e is the real permittivity, a is the conductivity, j2 = _1 and o0 is the angular frequency. When Re{f(g*p,8*m) } > 0 , the effective moment is aligned with the electric field vector E. Conversely, when Re{f(e*p,g*m) } _ Re{f(g*p, g'm) } _ > - 1 / 2 As outlined, the Clausius Mosotti factor can be either positive or negative (or zero); so the force on a particle can act to direct a particle either towards or away from a region of high electric field strength. These two conditions are shown in Figure 5.1. Equation (5.3) is valid for a homogeneous particle. However, we know that living cells are far from homogeneous. Namely, they consist of cellular membrane and cytoplasm. Assume that a spherical living cell consists of a cytoplasm with permittivity C,n, conductivity %, and radius r enclosed by cellular membrane of permittivity e,c and thickness 6. As shown by Kaler and Jones (1990), at frequencies higher than 10 kHz the sinusoidal steady-state
112
C h a p t e r 5. H u n t f o r Cells in an Electric Field
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F I G U R E S. 1. Two different particles (cells) in a nonuniform electric field. The cell on the left is more polarizable than the surrounding medium and is attracted towards the strong field at the pin electrode; the cell of low polarizability on the right is directed away from the strong field region.
dielectric response of a spherical living cell can be represented by an equivalent homogeneous sphere of radius r + i5 and the complex permittivity
g'cell, where ~'*cel,
=
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+ 1:2)+ 1]
(5.4)
Here, Cm = *'c/b is the cell membrane capacitance per unit area, and ~1 = C,p/~p and ~2 Cmr/~p are time constants. As follows from Eq. (5.3), the force acting on a cell in a nonuniform electric field is dependent on its dimensions. Besides, as derived from the definition of the Clausius-Mosotti factor, the force depends on dielectric properties of cytoplasm as well. Thus, mobility of cells in the electric field is a rather complex function of their dimensions and shape as well as of dielectric parameters of cytoplasm and cellular membrane. Thereby, the dependence of the Clausius-Mosotti factor on the electric field frequency allows for a wide range variation of the force acting on a cell. =
Cell ID in an Alternating Electric Field
113
Now let us return to the problem we posed at the beginning of this chapter: How can we bring the two living cells to be fused so close that they touch? Assume two cells of the same type are close to each other, but out of contact. If the electric field is induced in the solution so that the line joining the cells is parallel to the field strength vector (Figure 5.2), the cells become polarized. As a result, if the cells are located close enough to each other they become attracted to each other due to the interaction of opposite poles of their dipoles. As this theoretical development implies, bringing cells closer can be speeded up if a region of the minimal electric field strength is placed between them, whereas their dipole moment is rendered negative by way of appropriate selection of the field frequency.
Cell ID in an Alternating Electric Field However, using dielectrophoresis for bringing cells closer before their fusion is but one of its possible applications. At present the most popular field where dielectrophoresis is used appears to be the cell separation. Cell separation has numerous applications in medicine and biotechnology. For example, the isolation of cancer cells from blood and bone marrow is critical
FIGURE 5 . 2 . Bringing cells with negative dipole moments closer in the region of minimal field strength. Mediated by dielectrophoretic forces.
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114
Chapter 5. Hunt for Cells in an Electric Field
for the early diagnosis of disease and for its monitoring during and after therapy. As follows from the principles of dielectrophoresis, the electromechanical response of the cell is a complex function of the applied field frequency as well as dielectric parameters of the cell such as the cell membrane dielectric constant and conductance, the conductance and dielectric constant of the cytoplasm, cell size, etc. This implies that, in principle, different cells can be separated from each other by being placed in an alternating electric field, after determining their dielectric parameters. As a rule, the frequency dependence of dielectric parameters of living cells is studied through the use of electrorotation (Arnold and Zimmermann, 1988). To make cells rotate in alternating electric field without displacing them relative to the optical axis of microscope lens, we use the system of electrodes shown in Figure 5.3, with a 90 degree phase difference between adjacent electrodes. As a result, a rotating electric field is generated, and the resulting rotational torque exerted on a particle is given by: T = mxE
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(5.5)
Equation (5.5) shows that the torque depends only on the electric field vector and not on the field gradient. The value of the phase difference between the induced dipole m, and the field vector E controls the magnitude of the torque, reaching maximum when the phase difference is 90 degrees, and zero when the phase is zero. Thus a cell in a rotating electric field will rotate asynchronously with the field. It can be shown that the torque depends only on the imaginary component of the dipole moment and so the time-averaged torque on a cell of radius r is:
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T(,o)
-
-4rt,:,,,r3lm{/'(,:*n, ,:*,,,)}E2
(5.6)
For example, if the imaginary component of m is positive, then the torque exerted will be negative and cause the particle to rotate in antifield direction (Figure 5.3(b)). It follows from Eq. (5.6) that if a cell is placed between electrodes as shown in Figure 5.3, and the angular rate of rotation of cells in the rotating field is measured, the dependence of the angular rate on electric field frequency will coincide with the frequency dependence of the imaginary part
Cell ID in an A l t e r n a t i n g Electric Field
115
FIG U R E 5 . 3 . (a) A rotating field can be generated between four electrodes by applying sinusoidal voltages to them with phases spaced 90 ~ apart. (b) Depending upon the phase angle between the induced dipole moment m and E, defined by Eq. (5.2), the rotational torque acting on the cell will be either co- or anti-field. In this case, the cell will rotate counter to the clockwise rotating field. Spacing between electrode tips is about several hundred microns.
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zyxwvu
of the Clausius-Mosotti factor f(~;*p,~;*m)" With the frequency dependence for Im{f(~.*p, e'm)} known, that for Re{f(~.*p, e.*m)}is found fairly easily, as it was done, for instance, in Becker et al. (1995) for human breast cancer cells, erythrocytes, and lymphocytes (see Figure 5.4). The frequency dependence of the Clausius-Mosotti factor has proven to be different for different types
116
Chapter 5. Hunt for Cells in an Electric Field
of cells, and, therefore, it can serve as their ID for conducting the electromechanical manipulations in electric fields.
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Cell Separation Using Traveling-Wave Dielectrophoresis
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The system of two rows of electrodes given in Figure 5.5 makes it possible to obtain a traveling wave of electric field in the space between the rows. As shown by Huang et al. (1993), the time-averaged force F(oo) acting on a particle in the center of the channel formed between the electrode arrangement pictured on Figure 5.5 can be written as F(oo) = - I m { m ( o ) ) E r c / 2
(5.7)
where E is the field strength across the channel and 2 is the wavelength of the traveling field of value equal to the distance (measured along the channel) between the closest electrodes of the same phase. Obviously, away from the center of the channel and near the electrode tips, the force acting on the particle becomes more complicated and not describable by Eq. (5.7). The dielectrophoretic force F is balanced by viscous drag (given by Stoke's equation). So, considering the traveling-wave dielectrophoresis in a medium of viscosity r/, the velocity u of a cell traveling along the array is represented by: u -- --2rCgmr2Im{f(c*p, g,*m)E2 /(35[F1)
zyxw (5.8)
The motion of cells along the channel, induced by traveling-wave dielectrophoresis and described by Eq. (5.8), enables separation of living cells from the dead ones. Living cells, with the imaginary part of dipole moment being positive, move to the left; dead ones, with the same being negative, move to the right (see Figure 5.5). Bear in mind here that only those cells that have negative real part of dipole moment will move along the channel between the electrodes since only these cells will strive towards the central axis of the channel, where the region with minimal field intensity is located. Therefore, once the field is on, all the cells possessing positive dipole
Cell S e p a r a t i o n
Using Traveling-Wave
117
Dielectrophoresis
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frequency, Hz F I G U R E 5 . 4 . Top: frequency dependence of angular rate for rotation of human breast cancer cells (m) and lymphocytes ( . . . . ) in isotonic sucrose with conductivity of 56 mS/m. Bottom: frequency dependence of Re{f(~*p, r'm)} calculated from data shown on upper panel; fl and f2 are frequencies at which Re{ f(C,*p, ~'*m)} goes through zero for cancer cells and lymphocytes, respectively. (Modified from Becker et al., 1995. Republished with permission of the Proceedings of the National Academy of Sciences USA, 2101 Constitution Ave., NW, Washington, DC 20418. "Separation of human breast cancer cells from blood by differential dielectric affinity" (Figure 2). F. F. Becker, et al. 1995, Vol. 92. Reproduced by permission of the publisher via Copyright Clearance Center, Inc.)
118
Chapter 5. Hunt for Cells in an Electric Field
F I G U R E 5 . 5 . Cell motion (closed arrows) induced by an electric wave that travels from left to right (open arrows) between electrode system energized by cosine voltage of the indicated phase relationships; A - - m o t i o n expected for a viable cell for field frequency at which Re{m(u~)} 0 simultaneously; Bmmotion of a nonviable cell with damaged membrane for field frequency at which Re{m(.~) }